diff --git a/README.md b/README.md index 4269b211..337a8b23 100644 --- a/README.md +++ b/README.md @@ -75,6 +75,16 @@ llm-web-kit is a python library that .. ## Quick Start +![extract_method picture](/docs/images/extract_method.png) + +This diagram shows three main HTML content extraction methods: + +1. **extract by magic_html+recognize**: Two-stage complete extraction that first uses magic-html to extract main content, then converts it to structured markdown. + +2. **only extract by recognize**: Direct content recognition that converts main_html to structured format without main content identification. + +3. **only extract main_html by magic-html**: First-stage only extraction that identifies and extracts main content area while preserving HTML structure. + ### extract by magic_html+recognize ```python diff --git a/bench/data/groundtruth/math_katex_latex_1.jsonl b/bench/data/groundtruth/math_katex_latex_1.jsonl index 7de24ba4..9cde9573 100644 --- a/bench/data/groundtruth/math_katex_latex_1.jsonl +++ b/bench/data/groundtruth/math_katex_latex_1.jsonl @@ -1 +1 @@ -{"content_list": [[{"type": "title", "raw_content": "

Solve the cubic equation:

", "content": {"title_content": "Solve the cubic equation:", "level": "1"}}, {"type": "title", "raw_content": "

$$x^3+2x^2+8x+1=0 $$

", "content": {"title_content": "$$x^3+2x^2+8x+1=0 $$", "level": "2"}}, {"type": "paragraph", "raw_content": "

Quick Answer

", "content": [{"c": "Quick Answer", "t": "text"}]}, {"type": "paragraph", "raw_content": "

Since the discriminant

", "content": [{"c": "Since the discriminant", "t": "text"}]}, {"type": "equation-interline", "raw_content": "\\Delta >0", "content": {"math_content": "\\Delta >0", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

, the cubic equation has one real root and two conjugate complex roots.

", "content": [{"c": ", the cubic equation has one real root and two conjugate complex roots.", "t": "text"}]}, {"type": "equation-interline", "raw_content": " \\Delta=14.472222222222", "content": {"math_content": "\\Delta=14.472222222222", "math_type": "latex", "by": "katex"}}, {"type": "equation-interline", "raw_content": "\\begin{cases} x_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}-\\dfrac{2}{3} \\\\ x_2=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\\\ x_3=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)-\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\end{cases}", "content": {"math_content": "\\begin{cases} x_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}-\\dfrac{2}{3} \\\\ x_2=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\\\ x_3=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)-\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\end{cases}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

In decimals,

", "content": [{"c": "In decimals,", "t": "text"}]}, {"type": "equation-interline", "raw_content": "\\begin{cases} x_1=-0.12888523007843 \\\\ x_2=-0.93555738496079+2.6236564793854i \\\\ x_3=-0.93555738496079-2.6236564793854i \\end{cases}", "content": {"math_content": "\\begin{cases} x_1=-0.12888523007843 \\\\ x_2=-0.93555738496079+2.6236564793854i \\\\ x_3=-0.93555738496079-2.6236564793854i \\end{cases}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Detailed Steps on Solution

", "content": [{"c": "Detailed Steps on Solution", "t": "text"}]}, {"type": "title", "raw_content": "

1. Convert to depressed cubic equation

", "content": {"title_content": "1. Convert to depressed cubic equation", "level": "2"}}, {"type": "paragraph", "raw_content": "

The idea is to convert general form of cubic equation

", "content": [{"c": "The idea is to convert general form of cubic equation", "t": "text"}]}, {"type": "equation-interline", "raw_content": "ax^3+bx^2+cx+d = 0", "content": {"math_content": "ax^3+bx^2+cx+d = 0", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

to the form without quadratic term.

", "content": [{"c": "to the form without quadratic term.", "t": "text"}]}, {"type": "equation-interline", "raw_content": "t^3+pt+q = 0", "content": {"math_content": "t^3+pt+q = 0", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

By substituting

", "content": [{"c": "By substituting", "t": "text"}]}, {"type": "equation-interline", "raw_content": "x", "content": {"math_content": "x", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

with

", "content": [{"c": "with", "t": "text"}]}, {"type": "equation-interline", "raw_content": "t - \\dfrac{b}{3a}", "content": {"math_content": "t - \\dfrac{b}{3a}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

, the general cubic equation could be transformed to

", "content": [{"c": ", the general cubic equation could be transformed to", "t": "text"}]}, {"type": "equation-interline", "raw_content": "t^3+\\dfrac{3ac-b^2}{3a^2}t+\\dfrac{2b^3-9abc+27a^2d}{27a^3} = 0 ", "content": {"math_content": "t^3+\\dfrac{3ac-b^2}{3a^2}t+\\dfrac{2b^3-9abc+27a^2d}{27a^3} = 0", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Compare with the depressed cubic equation. Then,

", "content": [{"c": "Compare with the depressed cubic equation. Then,", "t": "text"}]}, {"type": "equation-interline", "raw_content": "p = \\dfrac{3ac-b^2}{3a^2}", "content": {"math_content": "p = \\dfrac{3ac-b^2}{3a^2}", "math_type": "latex", "by": "katex"}}, {"type": "equation-interline", "raw_content": "q = \\dfrac{2b^3-9abc+27a^2d}{27a^3} ", "content": {"math_content": "q = \\dfrac{2b^3-9abc+27a^2d}{27a^3}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Substitute the values of coefficients,

", "content": [{"c": "Substitute the values of coefficients,", "t": "text"}]}, {"type": "equation-interline", "raw_content": "p, q", "content": {"math_content": "p, q", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

is obtained as

", "content": [{"c": "is obtained as", "t": "text"}]}, {"type": "equation-interline", "raw_content": "p = \\dfrac{3\\cdot 1\\cdot 8-2^2}{3\\cdot 1^2}=\\dfrac{20}{3}", "content": {"math_content": "p = \\dfrac{3\\cdot 1\\cdot 8-2^2}{3\\cdot 1^2}=\\dfrac{20}{3}", "math_type": "latex", "by": "katex"}}, {"type": "equation-interline", "raw_content": "q = \\dfrac{2\\cdot 2^3-9\\cdot1\\cdot 2\\cdot 8+27\\cdot 1^2\\cdot1}{27\\cdot 1^3}=-\\dfrac{101}{27}", "content": {"math_content": "q = \\dfrac{2\\cdot 2^3-9\\cdot1\\cdot 2\\cdot 8+27\\cdot 1^2\\cdot1}{27\\cdot 1^3}=-\\dfrac{101}{27}", "math_type": "latex", "by": "katex"}}, {"type": "title", "raw_content": "

Use the substitution to transform

", "content": {"title_content": "Use the substitution to transform", "level": "3"}}, {"type": "paragraph", "raw_content": "

Let

", "content": [{"c": "Let", "t": "text"}]}, {"type": "equation-interline", "raw_content": "p", "content": {"math_content": "p", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

and

", "content": [{"c": "and", "t": "text"}]}, {"type": "equation-interline", "raw_content": "q", "content": {"math_content": "q", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

being the coefficient of the linean and constant terms, the depressed cubic equation is expressed as.

", "content": [{"c": "being the coefficient of the linean and constant terms, the depressed cubic equation is expressed as.", "t": "text"}]}, {"type": "equation-interline", "raw_content": "t^3 +pt+q=0", "content": {"math_content": "t^3 +pt+q=0", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Let

", "content": [{"c": "Let", "t": "text"}]}, {"type": "equation-interline", "raw_content": "x=t-\\dfrac{2}{3}", "content": {"math_content": "x=t-\\dfrac{2}{3}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

The cubic equation

", "content": [{"c": "The cubic equation", "t": "text"}]}, {"type": "equation-interline", "raw_content": "x\u00b3 + 2x\u00b2 + 8x + 1=0", "content": {"math_content": "x\u00b3 + 2x\u00b2 + 8x + 1=0", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

is transformed to

", "content": [{"c": "is transformed to", "t": "text"}]}, {"type": "equation-interline", "raw_content": "t^3 +\\dfrac{20}{3}t-\\dfrac{101}{27}=0", "content": {"math_content": "t^3 +\\dfrac{20}{3}t-\\dfrac{101}{27}=0", "math_type": "latex", "by": "katex"}}, {"type": "title", "raw_content": "

2. Cardano's solution

", "content": {"title_content": "2. Cardano's solution", "level": "2"}}, {"type": "paragraph", "raw_content": "

Let

", "content": [{"c": "Let", "t": "text"}]}, {"type": "equation-interline", "raw_content": "t=u-v", "content": {"math_content": "t=u-v", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Cube both sides and extract common factor from two middle terms after expanding the bracket.

", "content": [{"c": "Cube both sides and extract common factor from two middle terms after expanding the bracket.", "t": "text"}]}, {"type": "equation-interline", "raw_content": "\\begin{aligned} \\\\t^3&=(u-v)^3\\\\ & =u^3-3u^2v+3uv^2-v^3\\\\ & =-3uv(u-v)+u^3-v^3\\\\ \\end{aligned}", "content": {"math_content": "\\begin{aligned} \\\\t^3&=(u-v)^3\\\\ & =u^3-3u^2v+3uv^2-v^3\\\\ & =-3uv(u-v)+u^3-v^3\\\\ \\end{aligned}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Since

", "content": [{"c": "Since", "t": "text"}]}, {"type": "equation-interline", "raw_content": "u-v=t", "content": {"math_content": "u-v=t", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

, substitution gives a linear term for the equation.\n Rearrange terms.

", "content": [{"c": ", substitution gives a linear term for the equation.\n Rearrange terms.", "t": "text"}]}, {"type": "equation-interline", "raw_content": "x^3+3uvx-u^3+v^3=0", "content": {"math_content": "x^3+3uvx-u^3+v^3=0", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Compare the cubic equation with the original one (1)

", "content": [{"c": "Compare the cubic equation with the original one (1)", "t": "text"}]}, {"type": "equation-interline", "raw_content": "\\begin{cases} 3uv=\\dfrac{20}{3}\\quad\\text{or}\\quad v=\\dfrac{20}{9u}\\\\ v^3-u^3=-\\dfrac{101}{27}\\\\ \\end{cases}", "content": {"math_content": "\\begin{cases} 3uv=\\dfrac{20}{3}\\quad\\text{or}\\quad v=\\dfrac{20}{9u}\\\\ v^3-u^3=-\\dfrac{101}{27}\\\\ \\end{cases}", "math_type": "latex", "by": "katex"}}, {"type": "equation-interline", "raw_content": "v=\\dfrac{20}{9u}", "content": {"math_content": "v=\\dfrac{20}{9u}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

gives relationship between the two variables. Substitute the value of

", "content": [{"c": "gives relationship between the two variables. Substitute the value of", "t": "text"}]}, {"type": "equation-interline", "raw_content": "v", "content": {"math_content": "v", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

to the second equation

", "content": [{"c": "to the second equation", "t": "text"}]}, {"type": "equation-interline", "raw_content": "\\Big(\\dfrac{20}{9u}\\Big)^3-u^3=-\\dfrac{101}{27}", "content": {"math_content": "\\Big(\\dfrac{20}{9u}\\Big)^3-u^3=-\\dfrac{101}{27}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Simplifying gives,

", "content": [{"c": "Simplifying gives,", "t": "text"}]}, {"type": "equation-interline", "raw_content": "u^3-\\dfrac{8000}{729}\\dfrac{1}{u^3}-\\dfrac{101}{27}=0", "content": {"math_content": "u^3-\\dfrac{8000}{729}\\dfrac{1}{u^3}-\\dfrac{101}{27}=0", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

2

", "content": [{"c": "2", "t": "text"}]}, {"type": "paragraph", "raw_content": "

Let

", "content": [{"c": "Let", "t": "text"}]}, {"type": "equation-interline", "raw_content": "m=u^3", "content": {"math_content": "m=u^3", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

, then the equation is transformed to a quadratic equation in terms of $$m$$.\n Once the value of $$m$$ is determined, $$v^3$$ could be determined by

", "content": [{"c": ", then the equation is transformed to a quadratic equation in terms of $$m$$.\n Once the value of $$m$$ is determined, $$v^3$$ could be determined by", "t": "text"}]}, {"type": "equation-interline", "raw_content": "v^3=-\\dfrac{101}{27}+u^3", "content": {"math_content": "v^3=-\\dfrac{101}{27}+u^3", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

.

", "content": [{"c": ".", "t": "text"}]}, {"type": "equation-interline", "raw_content": "m^2-\\dfrac{101}{27}m-\\dfrac{8000}{729}=0", "content": {"math_content": "m^2-\\dfrac{101}{27}m-\\dfrac{8000}{729}=0", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Sovling the quadratic euqation will give two roots (some may be equal). Here we only cosider\n one case with positive sign before the square root radical since the negative case will produce the same result.

", "content": [{"c": "Sovling the quadratic euqation will give two roots (some may be equal). Here we only cosider\n one case with positive sign before the square root radical since the negative case will produce the same result.", "t": "text"}]}, {"type": "equation-interline", "raw_content": "\\begin{aligned} \\\\u^3=m&=\\dfrac{101}{54}+\\dfrac{1}{2}\\sqrt{\\Big(-\\dfrac{101}{27}^2\\Big)-4\\cdot \\Big(-\\dfrac{8000}{729}\\Big)}\\\\ & =\\dfrac{101}{54}+\\dfrac{1}{2}\\sqrt{\\dfrac{10201}{729}+\\dfrac{32000}{729}}\\\\ & =\\dfrac{101}{54}+\\dfrac{1}{2}\\sqrt{\\dfrac{521}{9}}\\\\ & =\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\\\ \\end{aligned}", "content": {"math_content": "\\begin{aligned} \\\\u^3=m&=\\dfrac{101}{54}+\\dfrac{1}{2}\\sqrt{\\Big(-\\dfrac{101}{27}^2\\Big)-4\\cdot \\Big(-\\dfrac{8000}{729}\\Big)}\\\\ & =\\dfrac{101}{54}+\\dfrac{1}{2}\\sqrt{\\dfrac{10201}{729}+\\dfrac{32000}{729}}\\\\ & =\\dfrac{101}{54}+\\dfrac{1}{2}\\sqrt{\\dfrac{521}{9}}\\\\ & =\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\\\ \\end{aligned}", "math_type": "latex", "by": "katex"}}, {"type": "equation-interline", "raw_content": "v^3", "content": {"math_content": "v^3", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

can be determined by the equation we deduced

", "content": [{"c": "can be determined by the equation we deduced", "t": "text"}]}, {"type": "equation-interline", "raw_content": "v^3-u^3=-\\dfrac{101}{27}", "content": {"math_content": "v^3-u^3=-\\dfrac{101}{27}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

. Then,

", "content": [{"c": ". Then,", "t": "text"}]}, {"type": "equation-interline", "raw_content": "\\begin{aligned} \\\\v^3&=-\\dfrac{101}{27}+u^3\\\\ & =-\\dfrac{101}{27}+\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\\\ & =-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\\\ \\end{aligned}", "content": {"math_content": "\\begin{aligned} \\\\v^3&=-\\dfrac{101}{27}+u^3\\\\ & =-\\dfrac{101}{27}+\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\\\ & =-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\\\ \\end{aligned}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Now we have,

", "content": [{"c": "Now we have,", "t": "text"}]}, {"type": "equation-interline", "raw_content": "u^3=\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}", "content": {"math_content": "u^3=\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

and

", "content": [{"c": "and", "t": "text"}]}, {"type": "equation-interline", "raw_content": "v^3=-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}", "content": {"math_content": "v^3=-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Evaluating the simplest cubic equation

", "content": [{"c": "Evaluating the simplest cubic equation", "t": "text"}]}, {"type": "equation-interline", "raw_content": "x^3-A=0", "content": {"math_content": "x^3-A=0", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

,\n it has 3 roots, in which the first root is a real number . The second and third are\n expressed in the product of cubic root of unity and the first one.

", "content": [{"c": ",\n it has 3 roots, in which the first root is a real number . The second and third are\n expressed in the product of cubic root of unity and the first one.", "t": "text"}]}, {"type": "paragraph", "raw_content": "

If

", "content": [{"c": "If", "t": "text"}]}, {"type": "equation-interline", "raw_content": "\u03c9 = \\dfrac{-1+i\\sqrt{3}}{2}", "content": {"math_content": "\u03c9 = \\dfrac{-1+i\\sqrt{3}}{2}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

, then its reciprocal is equal to its conjugate,

", "content": [{"c": ", then its reciprocal is equal to its conjugate,", "t": "text"}]}, {"type": "equation-interline", "raw_content": "\\dfrac{1}{\u03c9}=\\overline{\u03c9}", "content": {"math_content": "\\dfrac{1}{\u03c9}=\\overline{\u03c9}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

.

", "content": [{"c": ".", "t": "text"}]}, {"type": "equation-interline", "raw_content": "\\begin{cases} r_1=\\sqrt[3]{A}\\\\ r_2=\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{A}\\\\ r_3=\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{A}\\\\ \\end{cases}", "content": {"math_content": "\\begin{cases} r_1=\\sqrt[3]{A}\\\\ r_2=\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{A}\\\\ r_3=\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{A}\\\\ \\end{cases}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Similary, taking cubic root for

", "content": [{"c": "Similary, taking cubic root for", "t": "text"}]}, {"type": "equation-interline", "raw_content": "u^3", "content": {"math_content": "u^3", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

and

", "content": [{"c": "and", "t": "text"}]}, {"type": "equation-interline", "raw_content": "v^3", "content": {"math_content": "v^3", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

also gives 3 roots.

", "content": [{"c": "also gives 3 roots.", "t": "text"}]}, {"type": "equation-interline", "raw_content": "\\begin{cases} u_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ u_2=\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ u_3=\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{cases}", "content": {"math_content": "\\begin{cases} u_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ u_2=\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ u_3=\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{cases}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

For

", "content": [{"c": "For", "t": "text"}]}, {"type": "equation-interline", "raw_content": "v_2", "content": {"math_content": "v_2", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

and $$v_3$$, the complex numbers before radicals are the conjugates of\n those for $$u_2$$ and $$u_3$$, which can be verified by the reciprocal property\n of the cubic root of unity from the equation $$v=\\dfrac{20}{9u}$$. The radicand can be taken as the\n negative conjugate of that in $$u_1$$, $$u_2$$ and

", "content": [{"c": "and $$v_3$$, the complex numbers before radicals are the conjugates of\n those for $$u_2$$ and $$u_3$$, which can be verified by the reciprocal property\n of the cubic root of unity from the equation $$v=\\dfrac{20}{9u}$$. The radicand can be taken as the\n negative conjugate of that in $$u_1$$, $$u_2$$ and", "t": "text"}]}, {"type": "equation-interline", "raw_content": "u_3", "content": {"math_content": "u_3", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

, which is the same in value.

", "content": [{"c": ", which is the same in value.", "t": "text"}]}, {"type": "equation-interline", "raw_content": "\\begin{cases} v_1=\\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ v_2=\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ v_3=\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{cases}", "content": {"math_content": "\\begin{cases} v_1=\\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ v_2=\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ v_3=\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{cases}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Verification for the redicand in

", "content": [{"c": "Verification for the redicand in", "t": "text"}]}, {"type": "equation-interline", "raw_content": "v", "content": {"math_content": "v", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

.

", "content": [{"c": ".", "t": "text"}]}, {"type": "equation-interline", "raw_content": "\\begin{aligned} \\\\v_1&=\\dfrac{20}{9u_1}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{1}{\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{1}{\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\Big(\\dfrac{101}{54}\\Big)^2-\\Big(\\dfrac{\\sqrt{521}}{6}\\Big)^2}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\dfrac{10201}{2916}-\\dfrac{521}{36}}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\dfrac{-1\\cdot 20^3}{9^3}}}\\\\ & =-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{aligned}", "content": {"math_content": "\\begin{aligned} \\\\v_1&=\\dfrac{20}{9u_1}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{1}{\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{1}{\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\Big(\\dfrac{101}{54}\\Big)^2-\\Big(\\dfrac{\\sqrt{521}}{6}\\Big)^2}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\dfrac{10201}{2916}-\\dfrac{521}{36}}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\dfrac{-1\\cdot 20^3}{9^3}}}\\\\ & =-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{aligned}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Since

", "content": [{"c": "Since", "t": "text"}]}, {"type": "equation-interline", "raw_content": "x=u-v", "content": {"math_content": "x=u-v", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

, combining the real and imaginary parts gives\n 3 results for

", "content": [{"c": ", combining the real and imaginary parts gives\n 3 results for", "t": "text"}]}, {"type": "equation-interline", "raw_content": "t", "content": {"math_content": "t", "math_type": "latex", "by": "katex"}}, {"type": "equation-interline", "raw_content": "\\begin{aligned} \\\\t_1&=u_1-v_1\\\\ & =\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{aligned}", "content": {"math_content": "\\begin{aligned} \\\\t_1&=u_1-v_1\\\\ & =\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{aligned}", "math_type": "latex", "by": "katex"}}, {"type": "equation-interline", "raw_content": "\\begin{aligned} \\\\t_2&=u_2-v_2\\\\ & =\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\Big(\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}", "content": {"math_content": "\\begin{aligned} \\\\t_2&=u_2-v_2\\\\ & =\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\Big(\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}", "math_type": "latex", "by": "katex"}}, {"type": "equation-interline", "raw_content": "\\begin{aligned} \\\\t_3&=u_3-v_3\\\\ & =\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\Big(\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}", "content": {"math_content": "\\begin{aligned} \\\\t_3&=u_3-v_3\\\\ & =\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\Big(\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}", "math_type": "latex", "by": "katex"}}, {"type": "title", "raw_content": "

3. Vieta's Substitution

", "content": {"title_content": "3. Vieta's Substitution", "level": "2"}}, {"type": "paragraph", "raw_content": "

In Cardano' solution,

", "content": [{"c": "In Cardano' solution,", "t": "text"}]}, {"type": "equation-interline", "raw_content": "t", "content": {"math_content": "t", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

is defined as the difference of $$u$$ and\n $$v$$. If we substitute the value of $$v$$ (4) into (2), we get the\n equation. $$t=u-\\dfrac{20}{9u}$$. And then substitute the equation to the cubic equation\n

", "content": [{"c": "is defined as the difference of $$u$$ and\n $$v$$. If we substitute the value of $$v$$ (4) into (2), we get the\n equation. $$t=u-\\dfrac{20}{9u}$$. And then substitute the equation to the cubic equation", "t": "text"}]}, {"type": "equation-interline", "raw_content": "t^3+\\dfrac{20}{3}t-\\dfrac{101}{27}=0", "content": {"math_content": "t^3+\\dfrac{20}{3}t-\\dfrac{101}{27}=0", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

. This method is called Vieta's Substitution\n for solving a cubic equation, which simplied the Cardano' solution. The substitution\n expression can be obtained by the following formula directly.

", "content": [{"c": ". This method is called Vieta's Substitution\n for solving a cubic equation, which simplied the Cardano' solution. The substitution\n expression can be obtained by the following formula directly.", "t": "text"}]}, {"type": "equation-interline", "raw_content": "t=u-\\dfrac{p}{3u}", "content": {"math_content": "t=u-\\dfrac{p}{3u}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Substitute the expression

", "content": [{"c": "Substitute the expression", "t": "text"}]}, {"type": "equation-interline", "raw_content": "t=u-\\dfrac{20}{9u}", "content": {"math_content": "t=u-\\dfrac{20}{9u}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

to the cubic equation

", "content": [{"c": "to the cubic equation", "t": "text"}]}, {"type": "equation-interline", "raw_content": "\\Big(u-\\dfrac{20}{9u}\\Big)^3+\\dfrac{20}{3}\\Big(u-\\dfrac{20}{9u}\\Big)-\\dfrac{101}{27}=0", "content": {"math_content": "\\Big(u-\\dfrac{20}{9u}\\Big)^3+\\dfrac{20}{3}\\Big(u-\\dfrac{20}{9u}\\Big)-\\dfrac{101}{27}=0", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Expand brackets and cancel the like terms

", "content": [{"c": "Expand brackets and cancel the like terms", "t": "text"}]}, {"type": "equation-interline", "raw_content": "u^3-\\cancel{\\dfrac{20}{3}u^2\\dfrac{1}{u}}+\\cancel{\\dfrac{400}{27}u\\dfrac{1}{u^2}}-\\dfrac{8000}{729}\\dfrac{1}{u^3}+\\cancel{\\dfrac{20}{3}u}-\\cancel{\\dfrac{400}{27}\\dfrac{1}{u}}-\\dfrac{101}{27}=0", "content": {"math_content": "u^3-\\cancel{\\dfrac{20}{3}u^2\\dfrac{1}{u}}+\\cancel{\\dfrac{400}{27}u\\dfrac{1}{u^2}}-\\dfrac{8000}{729}\\dfrac{1}{u^3}+\\cancel{\\dfrac{20}{3}u}-\\cancel{\\dfrac{400}{27}\\dfrac{1}{u}}-\\dfrac{101}{27}=0", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Then we get the same equation as (2)

", "content": [{"c": "Then we get the same equation as (2)", "t": "text"}]}, {"type": "equation-interline", "raw_content": "u^3-\\dfrac{8000}{729}\\dfrac{1}{u^3}-\\dfrac{101}{27}=0", "content": {"math_content": "u^3-\\dfrac{8000}{729}\\dfrac{1}{u^3}-\\dfrac{101}{27}=0", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

The rest of the steps will be the same as those of Cardano's solution

", "content": [{"c": "The rest of the steps will be the same as those of Cardano's solution", "t": "text"}]}, {"type": "title", "raw_content": "

4. Euler's Solution

", "content": {"title_content": "4. Euler's Solution", "level": "2"}}, {"type": "title", "raw_content": "

$$t^3+\\dfrac{20}{3}t-\\dfrac{101}{27}=0$$

", "content": {"title_content": "$$t^3+\\dfrac{20}{3}t-\\dfrac{101}{27}=0$$", "level": "2"}}, {"type": "paragraph", "raw_content": "

Move the linear term and constant of (1) to its right hand side.\n We get the following form of the equation.

", "content": [{"c": "Move the linear term and constant of (1) to its right hand side.\n We get the following form of the equation.", "t": "text"}]}, {"type": "equation-interline", "raw_content": "t^3=-\\dfrac{20}{3}t+\\dfrac{101}{27} ", "content": {"math_content": "t^3=-\\dfrac{20}{3}t+\\dfrac{101}{27}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

3

", "content": [{"c": "3", "t": "text"}]}, {"type": "paragraph", "raw_content": "

Let the root of the cubic equation be the sum of two cubic roots

", "content": [{"c": "Let the root of the cubic equation be the sum of two cubic roots", "t": "text"}]}, {"type": "equation-interline", "raw_content": "t=\\sqrt[3]{r_1}+\\sqrt[3]{r_2} ", "content": {"math_content": "t=\\sqrt[3]{r_1}+\\sqrt[3]{r_2}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

4

", "content": [{"c": "4", "t": "text"}]}, {"type": "paragraph", "raw_content": "

in which

", "content": [{"c": "in which", "t": "text"}]}, {"type": "equation-interline", "raw_content": "r_1", "content": {"math_content": "r_1", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

and

", "content": [{"c": "and", "t": "text"}]}, {"type": "equation-interline", "raw_content": "r_2", "content": {"math_content": "r_2", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

are two roots of a quadratic equation

", "content": [{"c": "are two roots of a quadratic equation", "t": "text"}]}, {"type": "equation-interline", "raw_content": "z^2-\\alpha z+ \u03b2=0 ", "content": {"math_content": "z^2-\\alpha z+ \u03b2=0", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

5

", "content": [{"c": "5", "t": "text"}]}, {"type": "paragraph", "raw_content": "

Using Vieta's Formula, the following equations are established.

", "content": [{"c": "Using Vieta's Formula, the following equations are established.", "t": "text"}]}, {"type": "equation-interline", "raw_content": "r_1+r_2 = \\alpha \\quad \\text{and} \\quad r_1r_2 = \u03b2 ", "content": {"math_content": "r_1+r_2 = \\alpha \\quad \\text{and} \\quad r_1r_2 = \u03b2", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

To determine

", "content": [{"c": "To determine", "t": "text"}]}, {"type": "equation-interline", "raw_content": "\\alpha", "content": {"math_content": "\\alpha", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

,

", "content": [{"c": ",", "t": "text"}]}, {"type": "equation-interline", "raw_content": "\u03b2", "content": {"math_content": "\u03b2", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

, cube both sides of the equation (4)

", "content": [{"c": ", cube both sides of the equation (4)", "t": "text"}]}, {"type": "equation-interline", "raw_content": "t^3=3\\sqrt[3]{r_1r_2}(\\sqrt[3]{r_1}+\\sqrt[3]{r_2})+r_1+r_2 ", "content": {"math_content": "t^3=3\\sqrt[3]{r_1r_2}(\\sqrt[3]{r_1}+\\sqrt[3]{r_2})+r_1+r_2", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Substituting, the equation is simplified to

", "content": [{"c": "Substituting, the equation is simplified to", "t": "text"}]}, {"type": "equation-interline", "raw_content": "t^3=3\\sqrt[3]{\u03b2}t+\\alpha ", "content": {"math_content": "t^3=3\\sqrt[3]{\u03b2}t+\\alpha", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Compare the cubic equation with (3), the following equations are established

", "content": [{"c": "Compare the cubic equation with (3), the following equations are established", "t": "text"}]}, {"type": "equation-interline", "raw_content": "\\begin{cases} 3\\sqrt[3]{\u03b2}=-\\dfrac{20}{3}\\\\ \\alpha=\\dfrac{101}{27}\\\\ \\end{cases}", "content": {"math_content": "\\begin{cases} 3\\sqrt[3]{\u03b2}=-\\dfrac{20}{3}\\\\ \\alpha=\\dfrac{101}{27}\\\\ \\end{cases}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Solving for

", "content": [{"c": "Solving for", "t": "text"}]}, {"type": "equation-interline", "raw_content": "\u03b2", "content": {"math_content": "\u03b2", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

gives

", "content": [{"c": "gives", "t": "text"}]}, {"type": "equation-interline", "raw_content": "\u03b2=-\\dfrac{8000}{729} ", "content": {"math_content": "\u03b2=-\\dfrac{8000}{729}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

So the quadratic equation (5) is determined as

", "content": [{"c": "So the quadratic equation (5) is determined as", "t": "text"}]}, {"type": "equation-interline", "raw_content": "z^2-\\dfrac{101}{27}z-\\dfrac{8000}{729}=0", "content": {"math_content": "z^2-\\dfrac{101}{27}z-\\dfrac{8000}{729}=0", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

6

", "content": [{"c": "6", "t": "text"}]}, {"type": "paragraph", "raw_content": "

Solving the quadratic equation yields

", "content": [{"c": "Solving the quadratic equation yields", "t": "text"}]}, {"type": "equation-interline", "raw_content": "\\begin{cases} r_1=\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\approx5.6746077738748\\\\ r_2=\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}\\approx-1.9338670331341\\\\ \\end{cases}", "content": {"math_content": "\\begin{cases} r_1=\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\approx5.6746077738748\\\\ r_2=\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}\\approx-1.9338670331341\\\\ \\end{cases}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Therefore, one of the roots of the cubic equation could be obtained from (4).

", "content": [{"c": "Therefore, one of the roots of the cubic equation could be obtained from (4).", "t": "text"}]}, {"type": "equation-interline", "raw_content": "t_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}} ", "content": {"math_content": "t_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

in decimals,

", "content": [{"c": "in decimals,", "t": "text"}]}, {"type": "equation-interline", "raw_content": "t_1=0.53778143658824 ", "content": {"math_content": "t_1=0.53778143658824", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

However, since the cube root of a quantity has triple values,

", "content": [{"c": "However, since the cube root of a quantity has triple values,", "t": "text"}]}, {"type": "paragraph", "raw_content": "

The other two roots could be determined as,

", "content": [{"c": "The other two roots could be determined as,", "t": "text"}]}, {"type": "equation-interline", "raw_content": "t_2=\\dfrac{-1+i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\dfrac{-1-i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}} ", "content": {"math_content": "t_2=\\dfrac{-1+i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\dfrac{-1-i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}", "math_type": "latex", "by": "katex"}}, {"type": "equation-interline", "raw_content": "t_3=\\dfrac{-1-i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\dfrac{-1+i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}} ", "content": {"math_content": "t_3=\\dfrac{-1-i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\dfrac{-1+i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Combining the real and imaginary parts\n results in the same result as that obtained by Cardano's solution.

", "content": [{"c": "Combining the real and imaginary parts\n results in the same result as that obtained by Cardano's solution.", "t": "text"}]}, {"type": "paragraph", "raw_content": "

For the equation

", "content": [{"c": "For the equation", "t": "text"}]}, {"type": "equation-interline", "raw_content": "t^3 +\\dfrac{20}{3}t-\\dfrac{101}{27}", "content": {"math_content": "t^3 +\\dfrac{20}{3}t-\\dfrac{101}{27}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

, we have $$p=\\dfrac{20}{3}$$ and

", "content": [{"c": ", we have $$p=\\dfrac{20}{3}$$ and", "t": "text"}]}, {"type": "equation-interline", "raw_content": "q = -\\dfrac{101}{27}", "content": {"math_content": "q = -\\dfrac{101}{27}", "math_type": "latex", "by": "katex"}}, {"type": "title", "raw_content": "

Calculate the discriminant

", "content": {"title_content": "Calculate the discriminant", "level": "3"}}, {"type": "paragraph", "raw_content": "

The nature of the roots are determined by the sign of the discriminant.

", "content": [{"c": "The nature of the roots are determined by the sign of the discriminant.", "t": "text"}]}, {"type": "equation-interline", "raw_content": "\\begin{aligned} \\\\\\Delta&=\\dfrac{q^2}{4}+\\dfrac{p^3}{27}\\\\ & =\\dfrac{\\Big(-\\dfrac{101}{27}\\Big)^2}{4}+\\dfrac{\\Big(\\dfrac{20}{3}\\Big)^3}{27}\\\\ & =\\dfrac{10201}{2916}+\\dfrac{8000}{729}\\\\ & =\\dfrac{10201\\cdot 1+8000\\cdot 4}{2916}\\\\ & =14.472222222222\\\\ \\end{aligned}", "content": {"math_content": "\\begin{aligned} \\\\\\Delta&=\\dfrac{q^2}{4}+\\dfrac{p^3}{27}\\\\ & =\\dfrac{\\Big(-\\dfrac{101}{27}\\Big)^2}{4}+\\dfrac{\\Big(\\dfrac{20}{3}\\Big)^3}{27}\\\\ & =\\dfrac{10201}{2916}+\\dfrac{8000}{729}\\\\ & =\\dfrac{10201\\cdot 1+8000\\cdot 4}{2916}\\\\ & =14.472222222222\\\\ \\end{aligned}", "math_type": "latex", "by": "katex"}}, {"type": "title", "raw_content": "

4.1 Use the root formula directly

", "content": {"title_content": "4.1 Use the root formula directly", "level": "3"}}, {"type": "paragraph", "raw_content": "

If the discriminant is greater than zero, we can use the root formula to determine the roots of the cubic equation.

", "content": [{"c": "If the discriminant is greater than zero, we can use the root formula to determine the roots of the cubic equation.", "t": "text"}]}, {"type": "equation-interline", "raw_content": "t_{1,2,3} =\\begin{cases} \\sqrt[3]{-\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} } } +\\sqrt[3]{-\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }}& \\\\ \u03c9\\cdotp \\sqrt[3]{-\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} } } + \\overline{\u03c9} \\sqrt[3]{-\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }}&\\ \\\\ \\overline{\u03c9}\\cdotp \\sqrt[3]{-\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} } } + \u03c9\\cdotp \\sqrt[3]{-\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }} \\end{cases}", "content": {"math_content": "t_{1,2,3} =\\begin{cases} \\sqrt[3]{-\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} } } +\\sqrt[3]{-\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }}& \\\\ \u03c9\\cdotp \\sqrt[3]{-\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} } } + \\overline{\u03c9} \\sqrt[3]{-\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }}&\\ \\\\ \\overline{\u03c9}\\cdotp \\sqrt[3]{-\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} } } + \u03c9\\cdotp \\sqrt[3]{-\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }} \\end{cases}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

in which,

", "content": [{"c": "in which,", "t": "text"}]}, {"type": "equation-interline", "raw_content": " \u03c9 = \\dfrac{-1+i\\sqrt{3}}{2} ", "content": {"math_content": "\u03c9 = \\dfrac{-1+i\\sqrt{3}}{2}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

and

", "content": [{"c": "and", "t": "text"}]}, {"type": "equation-interline", "raw_content": " \\overline{\u03c9} =\\dfrac{-1-i\\sqrt{3}}{2}", "content": {"math_content": "\\overline{\u03c9} =\\dfrac{-1-i\\sqrt{3}}{2}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Substitute the values of

", "content": [{"c": "Substitute the values of", "t": "text"}]}, {"type": "equation-interline", "raw_content": "p, q", "content": {"math_content": "p, q", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

and

", "content": [{"c": "and", "t": "text"}]}, {"type": "equation-interline", "raw_content": "\\Delta", "content": {"math_content": "\\Delta", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

which we have calculated. Then,

", "content": [{"c": "which we have calculated. Then,", "t": "text"}]}, {"type": "equation-interline", "raw_content": "\\begin{aligned} \\\\t_1&=\\sqrt[3]{\\dfrac{101}{54}+\\sqrt{\\dfrac{42201}{2916}}}+\\sqrt[3]{\\dfrac{101}{54}-\\sqrt{\\dfrac{42201}{2916}}}\\\\ & =\\sqrt[3]{\\dfrac{101}{54}+\\sqrt{\\dfrac{521\\cdot\\cancel{81}}{36\\cdot\\cancel{81}}}}+\\sqrt[3]{\\dfrac{101}{54}-\\sqrt{\\dfrac{521\\cdot\\cancel{81}}{36\\cdot\\cancel{81}}}}\\\\ & =\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{aligned}", "content": {"math_content": "\\begin{aligned} \\\\t_1&=\\sqrt[3]{\\dfrac{101}{54}+\\sqrt{\\dfrac{42201}{2916}}}+\\sqrt[3]{\\dfrac{101}{54}-\\sqrt{\\dfrac{42201}{2916}}}\\\\ & =\\sqrt[3]{\\dfrac{101}{54}+\\sqrt{\\dfrac{521\\cdot\\cancel{81}}{36\\cdot\\cancel{81}}}}+\\sqrt[3]{\\dfrac{101}{54}-\\sqrt{\\dfrac{521\\cdot\\cancel{81}}{36\\cdot\\cancel{81}}}}\\\\ & =\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{aligned}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

If we denote

", "content": [{"c": "If we denote", "t": "text"}]}, {"type": "equation-interline", "raw_content": "R = -\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }", "content": {"math_content": "R = -\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }", "math_type": "latex", "by": "katex"}}, {"type": "equation-interline", "raw_content": "\\overline{R} = -\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }", "content": {"math_content": "\\overline{R} = -\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

then,

", "content": [{"c": "then,", "t": "text"}]}, {"type": "equation-interline", "raw_content": "\\sqrt[3]{R} = \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}", "content": {"math_content": "\\sqrt[3]{R} = \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

,

", "content": [{"c": ",", "t": "text"}]}, {"type": "equation-interline", "raw_content": "\\sqrt[3]{\\overline{R}} =\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}", "content": {"math_content": "\\sqrt[3]{\\overline{R}} =\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}", "math_type": "latex", "by": "katex"}}, {"type": "equation-interline", "raw_content": "\\begin{aligned} \\\\t_2&= \u03c9\\cdotp \\sqrt[3]{R}+ \\overline{\u03c9} \\sqrt[3]{\\overline{R} }\\\\ & =\\dfrac{-\\sqrt[3]{R}-\\sqrt[3]{\\overline{R} }}{2} +\\dfrac{\\sqrt{3}( \\sqrt[3]{R} - \\sqrt[3]{\\overline{R} }) }{2} i\\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\&+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}", "content": {"math_content": "\\begin{aligned} \\\\t_2&= \u03c9\\cdotp \\sqrt[3]{R}+ \\overline{\u03c9} \\sqrt[3]{\\overline{R} }\\\\ & =\\dfrac{-\\sqrt[3]{R}-\\sqrt[3]{\\overline{R} }}{2} +\\dfrac{\\sqrt{3}( \\sqrt[3]{R} - \\sqrt[3]{\\overline{R} }) }{2} i\\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\&+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}", "math_type": "latex", "by": "katex"}}, {"type": "equation-interline", "raw_content": "\\begin{aligned} \\\\t_3&= \\overline{\u03c9}\\cdotp \\sqrt[3]{R}+ \u03c9\\cdotp \\sqrt[3]{\\overline{R}}\\\\ & =\\dfrac{-\\sqrt[3]{R}-\\sqrt[3]{\\overline{R} }}{2} +\\dfrac{\\sqrt{3}(- \\sqrt[3]{R} + \\sqrt[3]{\\overline{R} }) }{2}i \\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\&-\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}", "content": {"math_content": "\\begin{aligned} \\\\t_3&= \\overline{\u03c9}\\cdotp \\sqrt[3]{R}+ \u03c9\\cdotp \\sqrt[3]{\\overline{R}}\\\\ & =\\dfrac{-\\sqrt[3]{R}-\\sqrt[3]{\\overline{R} }}{2} +\\dfrac{\\sqrt{3}(- \\sqrt[3]{R} + \\sqrt[3]{\\overline{R} }) }{2}i \\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\&-\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}", "math_type": "latex", "by": "katex"}}, {"type": "title", "raw_content": "

Roots of the general cubic equation

", "content": {"title_content": "Roots of the general cubic equation", "level": "2"}}, {"type": "paragraph", "raw_content": "

Since

", "content": [{"c": "Since", "t": "text"}]}, {"type": "equation-interline", "raw_content": "x = t - \\dfrac{b}{3a}", "content": {"math_content": "x = t - \\dfrac{b}{3a}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

, substituting the values of $$t$$, $$a$$ and

", "content": [{"c": ", substituting the values of $$t$$, $$a$$ and", "t": "text"}]}, {"type": "equation-interline", "raw_content": "b", "content": {"math_content": "b", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

gives

", "content": [{"c": "gives", "t": "text"}]}, {"type": "equation-interline", "raw_content": "x_1 = t_1-\\dfrac{2}{3}", "content": {"math_content": "x_1 = t_1-\\dfrac{2}{3}", "math_type": "latex", "by": "katex"}}, {"type": "equation-interline", "raw_content": "x_2 = t_2-\\dfrac{2}{3}", "content": {"math_content": "x_2 = t_2-\\dfrac{2}{3}", "math_type": "latex", "by": "katex"}}, {"type": "equation-interline", "raw_content": "x_3 = t_3-\\dfrac{2}{3}", "content": {"math_content": "x_3 = t_3-\\dfrac{2}{3}", "math_type": "latex", "by": "katex"}}, {"type": "title", "raw_content": "

5. Summary

", "content": {"title_content": "5. Summary", "level": "2"}}, {"type": "paragraph", "raw_content": "

In summary, we have tried the method of cubic root formula to explore the solutions of the equation. The cubic equation

", "content": [{"c": "In summary, we have tried the method of cubic root formula to explore the solutions of the equation. The cubic equation", "t": "text"}]}, {"type": "equation-interline", "raw_content": "x\u00b3 + 2x\u00b2 + 8x + 1=0", "content": {"math_content": "x\u00b3 + 2x\u00b2 + 8x + 1=0", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

is found to have one real root and two complex roots. Exact values and approximations are given below.

", "content": [{"c": "is found to have one real root and two complex roots. Exact values and approximations are given below.", "t": "text"}]}, {"type": "equation-interline", "raw_content": "\\begin{cases} x_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}-\\dfrac{2}{3} \\\\ x_2=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\\\ x_3=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)-\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\end{cases}", "content": {"math_content": "\\begin{cases} x_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}-\\dfrac{2}{3} \\\\ x_2=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\\\ x_3=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)-\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\end{cases}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

in decimal notation,

", "content": [{"c": "in decimal notation,", "t": "text"}]}, {"type": "equation-interline", "raw_content": "\\begin{cases} x_1=-0.12888523007843 \\\\ x_2=-0.93555738496079+2.6236564793854i \\\\ x_3=-0.93555738496079-2.6236564793854i \\end{cases}", "content": {"math_content": "\\begin{cases} x_1=-0.12888523007843 \\\\ x_2=-0.93555738496079+2.6236564793854i \\\\ x_3=-0.93555738496079-2.6236564793854i \\end{cases}", "math_type": "latex", "by": "katex"}}, {"type": "title", "raw_content": "

6. Graph for the function $$f(x) = x\u00b3 + 2x\u00b2 + 8x + 1$$

", "content": {"title_content": "6. Graph for the function $$f(x) = x\u00b3 + 2x\u00b2 + 8x + 1$$", "level": "2"}}, {"type": "paragraph", "raw_content": "

Since the discriminat is greater than zero, the curve of the cubic function

", "content": [{"c": "Since the discriminat is greater than zero, the curve of the cubic function", "t": "text"}]}, {"type": "equation-interline", "raw_content": "f(x) = x\u00b3 + 2x\u00b2 + 8x + 1", "content": {"math_content": "f(x) = x\u00b3 + 2x\u00b2 + 8x + 1", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

has one intersection point with the x-axis.

", "content": [{"c": "has one intersection point with the x-axis.", "t": "text"}]}, {"type": "title", "raw_content": "

More cubic equations

", "content": {"title_content": "More cubic equations", "level": "2"}}]], "main_html": "

Solve the cubic equation:

$$x^3+2x^2+8x+1=0 $$

Quick Answer

Since the discriminant

\\Delta >0

, the cubic equation has one real root and two conjugate complex roots.

\\Delta=14.472222222222\\begin{cases} x_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}-\\dfrac{2}{3} \\\\ x_2=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\\\ x_3=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)-\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\end{cases}

In decimals,

\\begin{cases} x_1=-0.12888523007843 \\\\ x_2=-0.93555738496079+2.6236564793854i \\\\ x_3=-0.93555738496079-2.6236564793854i \\end{cases}

Detailed Steps on Solution

1. Convert to depressed cubic equation

The idea is to convert general form of cubic equation

ax^3+bx^2+cx+d = 0

to the form without quadratic term.

t^3+pt+q = 0

By substituting

x

with

t - \\dfrac{b}{3a}

, the general cubic equation could be transformed to

t^3+\\dfrac{3ac-b^2}{3a^2}t+\\dfrac{2b^3-9abc+27a^2d}{27a^3} = 0

Compare with the depressed cubic equation. Then,

p = \\dfrac{3ac-b^2}{3a^2}q = \\dfrac{2b^3-9abc+27a^2d}{27a^3}

Substitute the values of coefficients,

p, q

is obtained as

p = \\dfrac{3\\cdot 1\\cdot 8-2^2}{3\\cdot 1^2}=\\dfrac{20}{3}q = \\dfrac{2\\cdot 2^3-9\\cdot1\\cdot 2\\cdot 8+27\\cdot 1^2\\cdot1}{27\\cdot 1^3}=-\\dfrac{101}{27}

Use the substitution to transform

Let

p

and

q

being the coefficient of the linean and constant terms, the depressed cubic equation is expressed as.

t^3 +pt+q=0

Let

x=t-\\dfrac{2}{3}

The cubic equation

x\u00b3 + 2x\u00b2 + 8x + 1=0

is transformed to

t^3 +\\dfrac{20}{3}t-\\dfrac{101}{27}=0

2. Cardano's solution

Let

t=u-v

Cube both sides and extract common factor from two middle terms after expanding the bracket.

\\begin{aligned} \\\\t^3&=(u-v)^3\\\\ & =u^3-3u^2v+3uv^2-v^3\\\\ & =-3uv(u-v)+u^3-v^3\\\\ \\end{aligned}

Since

u-v=t

, substitution gives a linear term for the equation.\n Rearrange terms.

x^3+3uvx-u^3+v^3=0

Compare the cubic equation with the original one (1)

\\begin{cases} 3uv=\\dfrac{20}{3}\\quad\\text{or}\\quad v=\\dfrac{20}{9u}\\\\ v^3-u^3=-\\dfrac{101}{27}\\\\ \\end{cases}v=\\dfrac{20}{9u}

gives relationship between the two variables. Substitute the value of

v

to the second equation

\\Big(\\dfrac{20}{9u}\\Big)^3-u^3=-\\dfrac{101}{27}

Simplifying gives,

u^3-\\dfrac{8000}{729}\\dfrac{1}{u^3}-\\dfrac{101}{27}=0

2

Let

m=u^3

, then the equation is transformed to a quadratic equation in terms of $$m$$.\n Once the value of $$m$$ is determined, $$v^3$$ could be determined by

v^3=-\\dfrac{101}{27}+u^3

.

m^2-\\dfrac{101}{27}m-\\dfrac{8000}{729}=0

Sovling the quadratic euqation will give two roots (some may be equal). Here we only cosider\n one case with positive sign before the square root radical since the negative case will produce the same result.

\\begin{aligned} \\\\u^3=m&=\\dfrac{101}{54}+\\dfrac{1}{2}\\sqrt{\\Big(-\\dfrac{101}{27}^2\\Big)-4\\cdot \\Big(-\\dfrac{8000}{729}\\Big)}\\\\ & =\\dfrac{101}{54}+\\dfrac{1}{2}\\sqrt{\\dfrac{10201}{729}+\\dfrac{32000}{729}}\\\\ & =\\dfrac{101}{54}+\\dfrac{1}{2}\\sqrt{\\dfrac{521}{9}}\\\\ & =\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\\\ \\end{aligned}v^3

can be determined by the equation we deduced

v^3-u^3=-\\dfrac{101}{27}

. Then,

\\begin{aligned} \\\\v^3&=-\\dfrac{101}{27}+u^3\\\\ & =-\\dfrac{101}{27}+\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\\\ & =-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\\\ \\end{aligned}

Now we have,

u^3=\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}

and

v^3=-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}

Evaluating the simplest cubic equation

x^3-A=0

,\n it has 3 roots, in which the first root is a real number . The second and third are\n expressed in the product of cubic root of unity and the first one.

If

\u03c9 = \\dfrac{-1+i\\sqrt{3}}{2}

, then its reciprocal is equal to its conjugate,

\\dfrac{1}{\u03c9}=\\overline{\u03c9}

.

\\begin{cases} r_1=\\sqrt[3]{A}\\\\ r_2=\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{A}\\\\ r_3=\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{A}\\\\ \\end{cases}

Similary, taking cubic root for

u^3

and

v^3

also gives 3 roots.

\\begin{cases} u_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ u_2=\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ u_3=\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{cases}

For

v_2

and $$v_3$$, the complex numbers before radicals are the conjugates of\n those for $$u_2$$ and $$u_3$$, which can be verified by the reciprocal property\n of the cubic root of unity from the equation $$v=\\dfrac{20}{9u}$$. The radicand can be taken as the\n negative conjugate of that in $$u_1$$, $$u_2$$ and

u_3

, which is the same in value.

\\begin{cases} v_1=\\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ v_2=\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ v_3=\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{cases}

Verification for the redicand in

v

.

\\begin{aligned} \\\\v_1&=\\dfrac{20}{9u_1}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{1}{\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{1}{\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\Big(\\dfrac{101}{54}\\Big)^2-\\Big(\\dfrac{\\sqrt{521}}{6}\\Big)^2}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\dfrac{10201}{2916}-\\dfrac{521}{36}}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\dfrac{-1\\cdot 20^3}{9^3}}}\\\\ & =-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{aligned}

Since

x=u-v

, combining the real and imaginary parts gives\n 3 results for

t\\begin{aligned} \\\\t_1&=u_1-v_1\\\\ & =\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{aligned}\\begin{aligned} \\\\t_2&=u_2-v_2\\\\ & =\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\Big(\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}\\begin{aligned} \\\\t_3&=u_3-v_3\\\\ & =\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\Big(\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}

3. Vieta's Substitution

In Cardano' solution,

t

is defined as the difference of $$u$$ and\n $$v$$. If we substitute the value of $$v$$ (4) into (2), we get the\n equation. $$t=u-\\dfrac{20}{9u}$$. And then substitute the equation to the cubic equation\n

t^3+\\dfrac{20}{3}t-\\dfrac{101}{27}=0

. This method is called Vieta's Substitution\n for solving a cubic equation, which simplied the Cardano' solution. The substitution\n expression can be obtained by the following formula directly.

t=u-\\dfrac{p}{3u}

Substitute the expression

t=u-\\dfrac{20}{9u}

to the cubic equation

\\Big(u-\\dfrac{20}{9u}\\Big)^3+\\dfrac{20}{3}\\Big(u-\\dfrac{20}{9u}\\Big)-\\dfrac{101}{27}=0

Expand brackets and cancel the like terms

u^3-\\cancel{\\dfrac{20}{3}u^2\\dfrac{1}{u}}+\\cancel{\\dfrac{400}{27}u\\dfrac{1}{u^2}}-\\dfrac{8000}{729}\\dfrac{1}{u^3}+\\cancel{\\dfrac{20}{3}u}-\\cancel{\\dfrac{400}{27}\\dfrac{1}{u}}-\\dfrac{101}{27}=0

Then we get the same equation as (2)

u^3-\\dfrac{8000}{729}\\dfrac{1}{u^3}-\\dfrac{101}{27}=0

The rest of the steps will be the same as those of Cardano's solution

4. Euler's Solution

$$t^3+\\dfrac{20}{3}t-\\dfrac{101}{27}=0$$

Move the linear term and constant of (1) to its right hand side.\n We get the following form of the equation.

t^3=-\\dfrac{20}{3}t+\\dfrac{101}{27}

3

Let the root of the cubic equation be the sum of two cubic roots

t=\\sqrt[3]{r_1}+\\sqrt[3]{r_2}

4

in which

r_1

and

r_2

are two roots of a quadratic equation

z^2-\\alpha z+ \u03b2=0

5

Using Vieta's Formula, the following equations are established.

r_1+r_2 = \\alpha \\quad \\text{and} \\quad r_1r_2 = \u03b2

To determine

\\alpha

,

\u03b2

, cube both sides of the equation (4)

t^3=3\\sqrt[3]{r_1r_2}(\\sqrt[3]{r_1}+\\sqrt[3]{r_2})+r_1+r_2

Substituting, the equation is simplified to

t^3=3\\sqrt[3]{\u03b2}t+\\alpha

Compare the cubic equation with (3), the following equations are established

\\begin{cases} 3\\sqrt[3]{\u03b2}=-\\dfrac{20}{3}\\\\ \\alpha=\\dfrac{101}{27}\\\\ \\end{cases}

Solving for

\u03b2

gives

\u03b2=-\\dfrac{8000}{729}

So the quadratic equation (5) is determined as

z^2-\\dfrac{101}{27}z-\\dfrac{8000}{729}=0

6

Solving the quadratic equation yields

\\begin{cases} r_1=\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\approx5.6746077738748\\\\ r_2=\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}\\approx-1.9338670331341\\\\ \\end{cases}

Therefore, one of the roots of the cubic equation could be obtained from (4).

t_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}

in decimals,

t_1=0.53778143658824

However, since the cube root of a quantity has triple values,

The other two roots could be determined as,

t_2=\\dfrac{-1+i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\dfrac{-1-i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}} t_3=\\dfrac{-1-i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\dfrac{-1+i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}

Combining the real and imaginary parts\n results in the same result as that obtained by Cardano's solution.

For the equation

t^3 +\\dfrac{20}{3}t-\\dfrac{101}{27}

, we have $$p=\\dfrac{20}{3}$$ and

q = -\\dfrac{101}{27}

Calculate the discriminant

The nature of the roots are determined by the sign of the discriminant.

\\begin{aligned} \\\\\\Delta&=\\dfrac{q^2}{4}+\\dfrac{p^3}{27}\\\\ & =\\dfrac{\\Big(-\\dfrac{101}{27}\\Big)^2}{4}+\\dfrac{\\Big(\\dfrac{20}{3}\\Big)^3}{27}\\\\ & =\\dfrac{10201}{2916}+\\dfrac{8000}{729}\\\\ & =\\dfrac{10201\\cdot 1+8000\\cdot 4}{2916}\\\\ & =14.472222222222\\\\ \\end{aligned}

4.1 Use the root formula directly

If the discriminant is greater than zero, we can use the root formula to determine the roots of the cubic equation.

t_{1,2,3} =\\begin{cases} \\sqrt[3]{-\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} } } +\\sqrt[3]{-\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }}& \\\\ \u03c9\\cdotp \\sqrt[3]{-\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} } } + \\overline{\u03c9} \\sqrt[3]{-\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }}&\\ \\\\ \\overline{\u03c9}\\cdotp \\sqrt[3]{-\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} } } + \u03c9\\cdotp \\sqrt[3]{-\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }} \\end{cases}

in which,

\u03c9 = \\dfrac{-1+i\\sqrt{3}}{2}

and

\\overline{\u03c9} =\\dfrac{-1-i\\sqrt{3}}{2}

Substitute the values of

p, q

and

\\Delta

which we have calculated. Then,

\\begin{aligned} \\\\t_1&=\\sqrt[3]{\\dfrac{101}{54}+\\sqrt{\\dfrac{42201}{2916}}}+\\sqrt[3]{\\dfrac{101}{54}-\\sqrt{\\dfrac{42201}{2916}}}\\\\ & =\\sqrt[3]{\\dfrac{101}{54}+\\sqrt{\\dfrac{521\\cdot\\cancel{81}}{36\\cdot\\cancel{81}}}}+\\sqrt[3]{\\dfrac{101}{54}-\\sqrt{\\dfrac{521\\cdot\\cancel{81}}{36\\cdot\\cancel{81}}}}\\\\ & =\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{aligned}

If we denote

R = -\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }\\overline{R} = -\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }

then,

\\sqrt[3]{R} = \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}

,

\\sqrt[3]{\\overline{R}} =\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\begin{aligned} \\\\t_2&= \u03c9\\cdotp \\sqrt[3]{R}+ \\overline{\u03c9} \\sqrt[3]{\\overline{R} }\\\\ & =\\dfrac{-\\sqrt[3]{R}-\\sqrt[3]{\\overline{R} }}{2} +\\dfrac{\\sqrt{3}( \\sqrt[3]{R} - \\sqrt[3]{\\overline{R} }) }{2} i\\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\&+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}\\begin{aligned} \\\\t_3&= \\overline{\u03c9}\\cdotp \\sqrt[3]{R}+ \u03c9\\cdotp \\sqrt[3]{\\overline{R}}\\\\ & =\\dfrac{-\\sqrt[3]{R}-\\sqrt[3]{\\overline{R} }}{2} +\\dfrac{\\sqrt{3}(- \\sqrt[3]{R} + \\sqrt[3]{\\overline{R} }) }{2}i \\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\&-\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}

Roots of the general cubic equation

Since

x = t - \\dfrac{b}{3a}

, substituting the values of $$t$$, $$a$$ and

b

gives

x_1 = t_1-\\dfrac{2}{3}x_2 = t_2-\\dfrac{2}{3}x_3 = t_3-\\dfrac{2}{3}

5. Summary

In summary, we have tried the method of cubic root formula to explore the solutions of the equation. The cubic equation

x\u00b3 + 2x\u00b2 + 8x + 1=0

is found to have one real root and two complex roots. Exact values and approximations are given below.

\\begin{cases} x_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}-\\dfrac{2}{3} \\\\ x_2=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\\\ x_3=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)-\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\end{cases}

in decimal notation,

\\begin{cases} x_1=-0.12888523007843 \\\\ x_2=-0.93555738496079+2.6236564793854i \\\\ x_3=-0.93555738496079-2.6236564793854i \\end{cases}

6. Graph for the function $$f(x) = x\u00b3 + 2x\u00b2 + 8x + 1$$

Since the discriminat is greater than zero, the curve of the cubic function

f(x) = x\u00b3 + 2x\u00b2 + 8x + 1

has one intersection point with the x-axis.

More cubic equations

", "statics": {"title": 14, "paragraph": 103, "paragraph.text": 103, "equation-interline": 105}, "url": "https://uniteasy.com/solver/cubicequation/x%5E3%2B2x%5E2%2B8x%2B1%3D0/", "content": "# Solve the cubic equation:\n\n## $$x^3+2x^2+8x+1=0 $$\n\nQuick Answer\n\nSince the discriminant\n\n$$\n\\Delta >0\n$$\n\n, the cubic equation has one real root and two conjugate complex roots.\n\n$$\n\\Delta=14.472222222222\n$$\n\n$$\n\\begin{cases} x_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}-\\dfrac{2}{3} \\\\ x_2=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\\\ x_3=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)-\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\end{cases}\n$$\n\nIn decimals,\n\n$$\n\\begin{cases} x_1=-0.12888523007843 \\\\ x_2=-0.93555738496079+2.6236564793854i \\\\ x_3=-0.93555738496079-2.6236564793854i \\end{cases}\n$$\n\nDetailed Steps on Solution\n\n## 1. Convert to depressed cubic equation\n\nThe idea is to convert general form of cubic equation\n\n$$\nax^3+bx^2+cx+d = 0\n$$\n\nto the form without quadratic term.\n\n$$\nt^3+pt+q = 0\n$$\n\nBy substituting\n\n$$\nx\n$$\n\nwith\n\n$$\nt - \\dfrac{b}{3a}\n$$\n\n, the general cubic equation could be transformed to\n\n$$\nt^3+\\dfrac{3ac-b^2}{3a^2}t+\\dfrac{2b^3-9abc+27a^2d}{27a^3} = 0\n$$\n\nCompare with the depressed cubic equation. Then,\n\n$$\np = \\dfrac{3ac-b^2}{3a^2}\n$$\n\n$$\nq = \\dfrac{2b^3-9abc+27a^2d}{27a^3}\n$$\n\nSubstitute the values of coefficients,\n\n$$\np, q\n$$\n\nis obtained as\n\n$$\np = \\dfrac{3\\cdot 1\\cdot 8-2^2}{3\\cdot 1^2}=\\dfrac{20}{3}\n$$\n\n$$\nq = \\dfrac{2\\cdot 2^3-9\\cdot1\\cdot 2\\cdot 8+27\\cdot 1^2\\cdot1}{27\\cdot 1^3}=-\\dfrac{101}{27}\n$$\n\n### Use the substitution to transform\n\nLet\n\n$$\np\n$$\n\nand\n\n$$\nq\n$$\n\nbeing the coefficient of the linean and constant terms, the depressed cubic equation is expressed as.\n\n$$\nt^3 +pt+q=0\n$$\n\nLet\n\n$$\nx=t-\\dfrac{2}{3}\n$$\n\nThe cubic equation\n\n$$\nx\u00b3 + 2x\u00b2 + 8x + 1=0\n$$\n\nis transformed to\n\n$$\nt^3 +\\dfrac{20}{3}t-\\dfrac{101}{27}=0\n$$\n\n## 2. Cardano's solution\n\nLet\n\n$$\nt=u-v\n$$\n\nCube both sides and extract common factor from two middle terms after expanding the bracket.\n\n$$\n\\begin{aligned} \\\\t^3&=(u-v)^3\\\\ & =u^3-3u^2v+3uv^2-v^3\\\\ & =-3uv(u-v)+u^3-v^3\\\\ \\end{aligned}\n$$\n\nSince\n\n$$\nu-v=t\n$$\n\n, substitution gives a linear term for the equation.\n Rearrange terms.\n\n$$\nx^3+3uvx-u^3+v^3=0\n$$\n\nCompare the cubic equation with the original one (1)\n\n$$\n\\begin{cases} 3uv=\\dfrac{20}{3}\\quad\\text{or}\\quad v=\\dfrac{20}{9u}\\\\ v^3-u^3=-\\dfrac{101}{27}\\\\ \\end{cases}\n$$\n\n$$\nv=\\dfrac{20}{9u}\n$$\n\ngives relationship between the two variables. Substitute the value of\n\n$$\nv\n$$\n\nto the second equation\n\n$$\n\\Big(\\dfrac{20}{9u}\\Big)^3-u^3=-\\dfrac{101}{27}\n$$\n\nSimplifying gives,\n\n$$\nu^3-\\dfrac{8000}{729}\\dfrac{1}{u^3}-\\dfrac{101}{27}=0\n$$\n\n2\n\nLet\n\n$$\nm=u^3\n$$\n\n, then the equation is transformed to a quadratic equation in terms of $$m$$.\n Once the value of $$m$$ is determined, $$v^3$$ could be determined by\n\n$$\nv^3=-\\dfrac{101}{27}+u^3\n$$\n\n.\n\n$$\nm^2-\\dfrac{101}{27}m-\\dfrac{8000}{729}=0\n$$\n\nSovling the quadratic euqation will give two roots (some may be equal). Here we only cosider\n one case with positive sign before the square root radical since the negative case will produce the same result.\n\n$$\n\\begin{aligned} \\\\u^3=m&=\\dfrac{101}{54}+\\dfrac{1}{2}\\sqrt{\\Big(-\\dfrac{101}{27}^2\\Big)-4\\cdot \\Big(-\\dfrac{8000}{729}\\Big)}\\\\ & =\\dfrac{101}{54}+\\dfrac{1}{2}\\sqrt{\\dfrac{10201}{729}+\\dfrac{32000}{729}}\\\\ & =\\dfrac{101}{54}+\\dfrac{1}{2}\\sqrt{\\dfrac{521}{9}}\\\\ & =\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\\\ \\end{aligned}\n$$\n\n$$\nv^3\n$$\n\ncan be determined by the equation we deduced\n\n$$\nv^3-u^3=-\\dfrac{101}{27}\n$$\n\n. Then,\n\n$$\n\\begin{aligned} \\\\v^3&=-\\dfrac{101}{27}+u^3\\\\ & =-\\dfrac{101}{27}+\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\\\ & =-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\\\ \\end{aligned}\n$$\n\nNow we have,\n\n$$\nu^3=\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\n$$\n\nand\n\n$$\nv^3=-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\n$$\n\nEvaluating the simplest cubic equation\n\n$$\nx^3-A=0\n$$\n\n,\n it has 3 roots, in which the first root is a real number . The second and third are\n expressed in the product of cubic root of unity and the first one.\n\nIf\n\n$$\n\u03c9 = \\dfrac{-1+i\\sqrt{3}}{2}\n$$\n\n, then its reciprocal is equal to its conjugate,\n\n$$\n\\dfrac{1}{\u03c9}=\\overline{\u03c9}\n$$\n\n.\n\n$$\n\\begin{cases} r_1=\\sqrt[3]{A}\\\\ r_2=\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{A}\\\\ r_3=\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{A}\\\\ \\end{cases}\n$$\n\nSimilary, taking cubic root for\n\n$$\nu^3\n$$\n\nand\n\n$$\nv^3\n$$\n\nalso gives 3 roots.\n\n$$\n\\begin{cases} u_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ u_2=\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ u_3=\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{cases}\n$$\n\nFor\n\n$$\nv_2\n$$\n\nand $$v_3$$, the complex numbers before radicals are the conjugates of\n those for $$u_2$$ and $$u_3$$, which can be verified by the reciprocal property\n of the cubic root of unity from the equation $$v=\\dfrac{20}{9u}$$. The radicand can be taken as the\n negative conjugate of that in $$u_1$$, $$u_2$$ and\n\n$$\nu_3\n$$\n\n, which is the same in value.\n\n$$\n\\begin{cases} v_1=\\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ v_2=\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ v_3=\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{cases}\n$$\n\nVerification for the redicand in\n\n$$\nv\n$$\n\n.\n\n$$\n\\begin{aligned} \\\\v_1&=\\dfrac{20}{9u_1}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{1}{\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{1}{\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\Big(\\dfrac{101}{54}\\Big)^2-\\Big(\\dfrac{\\sqrt{521}}{6}\\Big)^2}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\dfrac{10201}{2916}-\\dfrac{521}{36}}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\dfrac{-1\\cdot 20^3}{9^3}}}\\\\ & =-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{aligned}\n$$\n\nSince\n\n$$\nx=u-v\n$$\n\n, combining the real and imaginary parts gives\n 3 results for\n\n$$\nt\n$$\n\n$$\n\\begin{aligned} \\\\t_1&=u_1-v_1\\\\ & =\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{aligned}\n$$\n\n$$\n\\begin{aligned} \\\\t_2&=u_2-v_2\\\\ & =\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\Big(\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}\n$$\n\n$$\n\\begin{aligned} \\\\t_3&=u_3-v_3\\\\ & =\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\Big(\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}\n$$\n\n## 3. Vieta's Substitution\n\nIn Cardano' solution,\n\n$$\nt\n$$\n\nis defined as the difference of $$u$$ and\n $$v$$. If we substitute the value of $$v$$ (4) into (2), we get the\n equation. $$t=u-\\dfrac{20}{9u}$$. And then substitute the equation to the cubic equation\n\n$$\nt^3+\\dfrac{20}{3}t-\\dfrac{101}{27}=0\n$$\n\n. This method is called Vieta's Substitution\n for solving a cubic equation, which simplied the Cardano' solution. The substitution\n expression can be obtained by the following formula directly.\n\n$$\nt=u-\\dfrac{p}{3u}\n$$\n\nSubstitute the expression\n\n$$\nt=u-\\dfrac{20}{9u}\n$$\n\nto the cubic equation\n\n$$\n\\Big(u-\\dfrac{20}{9u}\\Big)^3+\\dfrac{20}{3}\\Big(u-\\dfrac{20}{9u}\\Big)-\\dfrac{101}{27}=0\n$$\n\nExpand brackets and cancel the like terms\n\n$$\nu^3-\\cancel{\\dfrac{20}{3}u^2\\dfrac{1}{u}}+\\cancel{\\dfrac{400}{27}u\\dfrac{1}{u^2}}-\\dfrac{8000}{729}\\dfrac{1}{u^3}+\\cancel{\\dfrac{20}{3}u}-\\cancel{\\dfrac{400}{27}\\dfrac{1}{u}}-\\dfrac{101}{27}=0\n$$\n\nThen we get the same equation as (2)\n\n$$\nu^3-\\dfrac{8000}{729}\\dfrac{1}{u^3}-\\dfrac{101}{27}=0\n$$\n\nThe rest of the steps will be the same as those of Cardano's solution\n\n## 4. Euler's Solution\n\n## $$t^3+\\dfrac{20}{3}t-\\dfrac{101}{27}=0$$\n\nMove the linear term and constant of (1) to its right hand side.\n We get the following form of the equation.\n\n$$\nt^3=-\\dfrac{20}{3}t+\\dfrac{101}{27}\n$$\n\n3\n\nLet the root of the cubic equation be the sum of two cubic roots\n\n$$\nt=\\sqrt[3]{r_1}+\\sqrt[3]{r_2}\n$$\n\n4\n\nin which\n\n$$\nr_1\n$$\n\nand\n\n$$\nr_2\n$$\n\nare two roots of a quadratic equation\n\n$$\nz^2-\\alpha z+ \u03b2=0\n$$\n\n5\n\nUsing Vieta's Formula, the following equations are established.\n\n$$\nr_1+r_2 = \\alpha \\quad \\text{and} \\quad r_1r_2 = \u03b2\n$$\n\nTo determine\n\n$$\n\\alpha\n$$\n\n,\n\n$$\n\u03b2\n$$\n\n, cube both sides of the equation (4)\n\n$$\nt^3=3\\sqrt[3]{r_1r_2}(\\sqrt[3]{r_1}+\\sqrt[3]{r_2})+r_1+r_2\n$$\n\nSubstituting, the equation is simplified to\n\n$$\nt^3=3\\sqrt[3]{\u03b2}t+\\alpha\n$$\n\nCompare the cubic equation with (3), the following equations are established\n\n$$\n\\begin{cases} 3\\sqrt[3]{\u03b2}=-\\dfrac{20}{3}\\\\ \\alpha=\\dfrac{101}{27}\\\\ \\end{cases}\n$$\n\nSolving for\n\n$$\n\u03b2\n$$\n\ngives\n\n$$\n\u03b2=-\\dfrac{8000}{729}\n$$\n\nSo the quadratic equation (5) is determined as\n\n$$\nz^2-\\dfrac{101}{27}z-\\dfrac{8000}{729}=0\n$$\n\n6\n\nSolving the quadratic equation yields\n\n$$\n\\begin{cases} r_1=\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\approx5.6746077738748\\\\ r_2=\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}\\approx-1.9338670331341\\\\ \\end{cases}\n$$\n\nTherefore, one of the roots of the cubic equation could be obtained from (4).\n\n$$\nt_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\n$$\n\nin decimals,\n\n$$\nt_1=0.53778143658824\n$$\n\nHowever, since the cube root of a quantity has triple values,\n\nThe other two roots could be determined as,\n\n$$\nt_2=\\dfrac{-1+i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\dfrac{-1-i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\n$$\n\n$$\nt_3=\\dfrac{-1-i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\dfrac{-1+i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\n$$\n\nCombining the real and imaginary parts\n results in the same result as that obtained by Cardano's solution.\n\nFor the equation\n\n$$\nt^3 +\\dfrac{20}{3}t-\\dfrac{101}{27}\n$$\n\n, we have $$p=\\dfrac{20}{3}$$ and\n\n$$\nq = -\\dfrac{101}{27}\n$$\n\n### Calculate the discriminant\n\nThe nature of the roots are determined by the sign of the discriminant.\n\n$$\n\\begin{aligned} \\\\\\Delta&=\\dfrac{q^2}{4}+\\dfrac{p^3}{27}\\\\ & =\\dfrac{\\Big(-\\dfrac{101}{27}\\Big)^2}{4}+\\dfrac{\\Big(\\dfrac{20}{3}\\Big)^3}{27}\\\\ & =\\dfrac{10201}{2916}+\\dfrac{8000}{729}\\\\ & =\\dfrac{10201\\cdot 1+8000\\cdot 4}{2916}\\\\ & =14.472222222222\\\\ \\end{aligned}\n$$\n\n### 4.1 Use the root formula directly\n\nIf the discriminant is greater than zero, we can use the root formula to determine the roots of the cubic equation.\n\n$$\nt_{1,2,3} =\\begin{cases} \\sqrt[3]{-\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} } } +\\sqrt[3]{-\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }}& \\\\ \u03c9\\cdotp \\sqrt[3]{-\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} } } + \\overline{\u03c9} \\sqrt[3]{-\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }}&\\ \\\\ \\overline{\u03c9}\\cdotp \\sqrt[3]{-\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} } } + \u03c9\\cdotp \\sqrt[3]{-\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }} \\end{cases}\n$$\n\nin which,\n\n$$\n\u03c9 = \\dfrac{-1+i\\sqrt{3}}{2}\n$$\n\nand\n\n$$\n\\overline{\u03c9} =\\dfrac{-1-i\\sqrt{3}}{2}\n$$\n\nSubstitute the values of\n\n$$\np, q\n$$\n\nand\n\n$$\n\\Delta\n$$\n\nwhich we have calculated. Then,\n\n$$\n\\begin{aligned} \\\\t_1&=\\sqrt[3]{\\dfrac{101}{54}+\\sqrt{\\dfrac{42201}{2916}}}+\\sqrt[3]{\\dfrac{101}{54}-\\sqrt{\\dfrac{42201}{2916}}}\\\\ & =\\sqrt[3]{\\dfrac{101}{54}+\\sqrt{\\dfrac{521\\cdot\\cancel{81}}{36\\cdot\\cancel{81}}}}+\\sqrt[3]{\\dfrac{101}{54}-\\sqrt{\\dfrac{521\\cdot\\cancel{81}}{36\\cdot\\cancel{81}}}}\\\\ & =\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{aligned}\n$$\n\nIf we denote\n\n$$\nR = -\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }\n$$\n\n$$\n\\overline{R} = -\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }\n$$\n\nthen,\n\n$$\n\\sqrt[3]{R} = \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\n$$\n\n,\n\n$$\n\\sqrt[3]{\\overline{R}} =\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\n$$\n\n$$\n\\begin{aligned} \\\\t_2&= \u03c9\\cdotp \\sqrt[3]{R}+ \\overline{\u03c9} \\sqrt[3]{\\overline{R} }\\\\ & =\\dfrac{-\\sqrt[3]{R}-\\sqrt[3]{\\overline{R} }}{2} +\\dfrac{\\sqrt{3}( \\sqrt[3]{R} - \\sqrt[3]{\\overline{R} }) }{2} i\\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\&+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}\n$$\n\n$$\n\\begin{aligned} \\\\t_3&= \\overline{\u03c9}\\cdotp \\sqrt[3]{R}+ \u03c9\\cdotp \\sqrt[3]{\\overline{R}}\\\\ & =\\dfrac{-\\sqrt[3]{R}-\\sqrt[3]{\\overline{R} }}{2} +\\dfrac{\\sqrt{3}(- \\sqrt[3]{R} + \\sqrt[3]{\\overline{R} }) }{2}i \\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\&-\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}\n$$\n\n## Roots of the general cubic equation\n\nSince\n\n$$\nx = t - \\dfrac{b}{3a}\n$$\n\n, substituting the values of $$t$$, $$a$$ and\n\n$$\nb\n$$\n\ngives\n\n$$\nx_1 = t_1-\\dfrac{2}{3}\n$$\n\n$$\nx_2 = t_2-\\dfrac{2}{3}\n$$\n\n$$\nx_3 = t_3-\\dfrac{2}{3}\n$$\n\n## 5. Summary\n\nIn summary, we have tried the method of cubic root formula to explore the solutions of the equation. The cubic equation\n\n$$\nx\u00b3 + 2x\u00b2 + 8x + 1=0\n$$\n\nis found to have one real root and two complex roots. Exact values and approximations are given below.\n\n$$\n\\begin{cases} x_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}-\\dfrac{2}{3} \\\\ x_2=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\\\ x_3=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)-\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\end{cases}\n$$\n\nin decimal notation,\n\n$$\n\\begin{cases} x_1=-0.12888523007843 \\\\ x_2=-0.93555738496079+2.6236564793854i \\\\ x_3=-0.93555738496079-2.6236564793854i \\end{cases}\n$$\n\n## 6. Graph for the function $$f(x) = x\u00b3 + 2x\u00b2 + 8x + 1$$\n\nSince the discriminat is greater than zero, the curve of the cubic function\n\n$$\nf(x) = x\u00b3 + 2x\u00b2 + 8x + 1\n$$\n\nhas one intersection point with the x-axis.\n\n## More cubic equations\n", "html": "\n\n\n\n\n\nSolve x^3+2x^2+8x+1=0 | Uniteasy.com\n\n\n\n\n\n\n\n\n\n\n\n \n
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Solve the cubic equation:

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$$x^3+2x^2+8x+1=0 $$

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Quick Answer

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Since the discriminant $$\\Delta >0$$, the cubic equation has one real root and two conjugate complex roots.

$$ \\Delta=14.472222222222$$

$$\\begin{cases} x_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}-\\dfrac{2}{3} \\\\ x_2=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\\\ x_3=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)-\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\end{cases}$$

In decimals,

$$\\begin{cases} x_1=-0.12888523007843 \\\\ x_2=-0.93555738496079+2.6236564793854i \\\\ x_3=-0.93555738496079-2.6236564793854i \\end{cases}$$

Detailed Steps on Solution

1. Convert to depressed cubic equation

The idea is to convert general form of cubic equation

$$ax^3+bx^2+cx+d = 0$$

to the form without quadratic term.

$$t^3+pt+q = 0$$

By substituting $$x$$ with $$t - \\dfrac{b}{3a}$$, the general cubic equation could be transformed to

$$t^3+\\dfrac{3ac-b^2}{3a^2}t+\\dfrac{2b^3-9abc+27a^2d}{27a^3} = 0 $$

Compare with the depressed cubic equation. Then,

$$p = \\dfrac{3ac-b^2}{3a^2}$$

$$q = \\dfrac{2b^3-9abc+27a^2d}{27a^3} $$

Substitute the values of coefficients, $$p, q$$ is obtained as

$$p = \\dfrac{3\\cdot 1\\cdot 8-2^2}{3\\cdot 1^2}=\\dfrac{20}{3}$$

$$q = \\dfrac{2\\cdot 2^3-9\\cdot1\\cdot 2\\cdot 8+27\\cdot 1^2\\cdot1}{27\\cdot 1^3}=-\\dfrac{101}{27}$$

Use the substitution to transform

Let $$p$$ and $$q$$ being the coefficient of the linean and constant terms, the depressed cubic equation is expressed as.

$$t^3 +pt+q=0$$

Let $$x=t-\\dfrac{2}{3}$$

The cubic equation $$x\u00b3 + 2x\u00b2 + 8x + 1=0$$ is transformed to

$$t^3 +\\dfrac{20}{3}t-\\dfrac{101}{27}=0$$

2. Cardano's solution

Let $$t=u-v$$

Cube both sides and extract common factor from two middle terms after expanding the bracket.

$$\\begin{aligned} \\\\t^3&=(u-v)^3\\\\ & =u^3-3u^2v+3uv^2-v^3\\\\ & =-3uv(u-v)+u^3-v^3\\\\ \\end{aligned}$$

Since $$u-v=t$$, substitution gives a linear term for the equation.\n Rearrange terms.

$$x^3+3uvx-u^3+v^3=0$$

Compare the cubic equation with the original one (1)

$$\\begin{cases} 3uv=\\dfrac{20}{3}\\quad\\text{or}\\quad v=\\dfrac{20}{9u}\\\\ v^3-u^3=-\\dfrac{101}{27}\\\\ \\end{cases}$$

$$v=\\dfrac{20}{9u}$$ gives relationship between the two variables. Substitute the value of $$v$$ to the second equation

$$\\Big(\\dfrac{20}{9u}\\Big)^3-u^3=-\\dfrac{101}{27}$$

Simplifying gives,

$$u^3-\\dfrac{8000}{729}\\dfrac{1}{u^3}-\\dfrac{101}{27}=0$$2

Let $$m=u^3$$, then the equation is transformed to a quadratic equation in terms of $$m$$.\n Once the value of $$m$$ is determined, $$v^3$$ could be determined by $$v^3=-\\dfrac{101}{27}+u^3$$.

$$m^2-\\dfrac{101}{27}m-\\dfrac{8000}{729}=0$$

Sovling the quadratic euqation will give two roots (some may be equal). Here we only cosider\n one case with positive sign before the square root radical since the negative case will produce the same result.

$$\\begin{aligned} \\\\u^3=m&=\\dfrac{101}{54}+\\dfrac{1}{2}\\sqrt{\\Big(-\\dfrac{101}{27}^2\\Big)-4\\cdot \\Big(-\\dfrac{8000}{729}\\Big)}\\\\ & =\\dfrac{101}{54}+\\dfrac{1}{2}\\sqrt{\\dfrac{10201}{729}+\\dfrac{32000}{729}}\\\\ & =\\dfrac{101}{54}+\\dfrac{1}{2}\\sqrt{\\dfrac{521}{9}}\\\\ & =\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\\\ \\end{aligned}$$

$$v^3$$ can be determined by the equation we deduced $$v^3-u^3=-\\dfrac{101}{27}$$. Then,

$$\\begin{aligned} \\\\v^3&=-\\dfrac{101}{27}+u^3\\\\ & =-\\dfrac{101}{27}+\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\\\ & =-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\\\ \\end{aligned}$$

Now we have,

$$u^3=\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}$$ and $$v^3=-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}$$

Evaluating the simplest cubic equation $$x^3-A=0$$,\n it has 3 roots, in which the first root is a real number . The second and third are\n expressed in the product of cubic root of unity and the first one.

If $$\u03c9 = \\dfrac{-1+i\\sqrt{3}}{2}$$, then its reciprocal is equal to its conjugate, $$\\dfrac{1}{\u03c9}=\\overline{\u03c9}$$.

$$\\begin{cases} r_1=\\sqrt[3]{A}\\\\ r_2=\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{A}\\\\ r_3=\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{A}\\\\ \\end{cases}$$

Similary, taking cubic root for $$u^3$$ and $$v^3$$ also gives 3 roots.

$$\\begin{cases} u_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ u_2=\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ u_3=\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{cases}$$

For $$v_2$$ and $$v_3$$, the complex numbers before radicals are the conjugates of\n those for $$u_2$$ and $$u_3$$, which can be verified by the reciprocal property\n of the cubic root of unity from the equation $$v=\\dfrac{20}{9u}$$. The radicand can be taken as the\n negative conjugate of that in $$u_1$$, $$u_2$$ and $$u_3$$, which is the same in value.

$$\\begin{cases} v_1=\\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ v_2=\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ v_3=\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{cases}$$

Verification for the redicand in $$v$$.

$$\\begin{aligned} \\\\v_1&=\\dfrac{20}{9u_1}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{1}{\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{1}{\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\Big(\\dfrac{101}{54}\\Big)^2-\\Big(\\dfrac{\\sqrt{521}}{6}\\Big)^2}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\dfrac{10201}{2916}-\\dfrac{521}{36}}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\dfrac{-1\\cdot 20^3}{9^3}}}\\\\ & =-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{aligned}$$

Since $$x=u-v$$, combining the real and imaginary parts gives\n 3 results for $$t$$

$$\\begin{aligned} \\\\t_1&=u_1-v_1\\\\ & =\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{aligned}$$

$$\\begin{aligned} \\\\t_2&=u_2-v_2\\\\ & =\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\Big(\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}$$

$$\\begin{aligned} \\\\t_3&=u_3-v_3\\\\ & =\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\Big(\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}$$

3. Vieta's Substitution

In Cardano' solution, $$t$$ is defined as the difference of $$u$$ and\n $$v$$. If we substitute the value of $$v$$ (4) into (2), we get the\n equation. $$t=u-\\dfrac{20}{9u}$$. And then substitute the equation to the cubic equation\n $$t^3+\\dfrac{20}{3}t-\\dfrac{101}{27}=0$$. This method is called Vieta's Substitution\n for solving a cubic equation, which simplied the Cardano' solution. The substitution\n expression can be obtained by the following formula directly.

$$t=u-\\dfrac{p}{3u}$$

Substitute the expression $$t=u-\\dfrac{20}{9u}$$ to the cubic equation

$$\\Big(u-\\dfrac{20}{9u}\\Big)^3+\\dfrac{20}{3}\\Big(u-\\dfrac{20}{9u}\\Big)-\\dfrac{101}{27}=0$$

Expand brackets and cancel the like terms

$$u^3-\\cancel{\\dfrac{20}{3}u^2\\dfrac{1}{u}}+\\cancel{\\dfrac{400}{27}u\\dfrac{1}{u^2}}-\\dfrac{8000}{729}\\dfrac{1}{u^3}+\\cancel{\\dfrac{20}{3}u}-\\cancel{\\dfrac{400}{27}\\dfrac{1}{u}}-\\dfrac{101}{27}=0$$

Then we get the same equation as (2)

$$u^3-\\dfrac{8000}{729}\\dfrac{1}{u^3}-\\dfrac{101}{27}=0$$

The rest of the steps will be the same as those of Cardano's solution

4. Euler's Solution

$$t^3+\\dfrac{20}{3}t-\\dfrac{101}{27}=0$$

Move the linear term and constant of (1) to its right hand side.\n We get the following form of the equation.

$$t^3=-\\dfrac{20}{3}t+\\dfrac{101}{27} $$3

Let the root of the cubic equation be the sum of two cubic roots

$$t=\\sqrt[3]{r_1}+\\sqrt[3]{r_2} $$4

in which $$r_1$$ and $$r_2$$ are two roots of a quadratic equation

$$z^2-\\alpha z+ \u03b2=0 $$5

Using Vieta's Formula, the following equations are established.

$$r_1+r_2 = \\alpha \\quad \\text{and} \\quad r_1r_2 = \u03b2 $$

To determine $$\\alpha$$, $$\u03b2$$, cube both sides of the equation (4)

$$t^3=3\\sqrt[3]{r_1r_2}(\\sqrt[3]{r_1}+\\sqrt[3]{r_2})+r_1+r_2 $$

Substituting, the equation is simplified to

$$t^3=3\\sqrt[3]{\u03b2}t+\\alpha $$

Compare the cubic equation with (3), the following equations are established

$$\\begin{cases} 3\\sqrt[3]{\u03b2}=-\\dfrac{20}{3}\\\\ \\alpha=\\dfrac{101}{27}\\\\ \\end{cases}$$

Solving for $$\u03b2$$ gives

$$\u03b2=-\\dfrac{8000}{729} $$

So the quadratic equation (5) is determined as

$$z^2-\\dfrac{101}{27}z-\\dfrac{8000}{729}=0$$6

Solving the quadratic equation yields

$$\\begin{cases} r_1=\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\approx5.6746077738748\\\\ r_2=\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}\\approx-1.9338670331341\\\\ \\end{cases}$$

Therefore, one of the roots of the cubic equation could be obtained from (4).

$$t_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}} $$

in decimals,

$$t_1=0.53778143658824 $$

However, since the cube root of a quantity has triple values,

The other two roots could be determined as,

$$t_2=\\dfrac{-1+i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\dfrac{-1-i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}} $$

$$t_3=\\dfrac{-1-i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\dfrac{-1+i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}} $$

Combining the real and imaginary parts\n results in the same result as that obtained by Cardano's solution.

For the equation $$t^3 +\\dfrac{20}{3}t-\\dfrac{101}{27}$$, we have $$p=\\dfrac{20}{3}$$ and $$q = -\\dfrac{101}{27}$$

Calculate the discriminant

The nature of the roots are determined by the sign of the discriminant.

$$\\begin{aligned} \\\\\\Delta&=\\dfrac{q^2}{4}+\\dfrac{p^3}{27}\\\\ & =\\dfrac{\\Big(-\\dfrac{101}{27}\\Big)^2}{4}+\\dfrac{\\Big(\\dfrac{20}{3}\\Big)^3}{27}\\\\ & =\\dfrac{10201}{2916}+\\dfrac{8000}{729}\\\\ & =\\dfrac{10201\\cdot 1+8000\\cdot 4}{2916}\\\\ & =14.472222222222\\\\ \\end{aligned}$$

4.1 Use the root formula directly

If the discriminant is greater than zero, we can use the root formula to determine the roots of the cubic equation.

$$t_{1,2,3} =\\begin{cases} \\sqrt[3]{-\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} } } +\\sqrt[3]{-\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }}& \\\\ \u03c9\\cdotp \\sqrt[3]{-\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} } } + \\overline{\u03c9} \\sqrt[3]{-\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }}&\\ \\\\ \\overline{\u03c9}\\cdotp \\sqrt[3]{-\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} } } + \u03c9\\cdotp \\sqrt[3]{-\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }} \\end{cases}$$

in which, $$ \u03c9 = \\dfrac{-1+i\\sqrt{3}}{2} $$ and $$ \\overline{\u03c9} =\\dfrac{-1-i\\sqrt{3}}{2}$$

Substitute the values of $$p, q$$ and $$\\Delta$$ which we have calculated. Then,

$$\\begin{aligned} \\\\t_1&=\\sqrt[3]{\\dfrac{101}{54}+\\sqrt{\\dfrac{42201}{2916}}}+\\sqrt[3]{\\dfrac{101}{54}-\\sqrt{\\dfrac{42201}{2916}}}\\\\ & =\\sqrt[3]{\\dfrac{101}{54}+\\sqrt{\\dfrac{521\\cdot\\cancel{81}}{36\\cdot\\cancel{81}}}}+\\sqrt[3]{\\dfrac{101}{54}-\\sqrt{\\dfrac{521\\cdot\\cancel{81}}{36\\cdot\\cancel{81}}}}\\\\ & =\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{aligned}$$

If we denote

$$R = -\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }$$

$$\\overline{R} = -\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }$$

then,

$$\\sqrt[3]{R} = \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}$$, $$\\sqrt[3]{\\overline{R}} =\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}$$

$$\\begin{aligned} \\\\t_2&= \u03c9\\cdotp \\sqrt[3]{R}+ \\overline{\u03c9} \\sqrt[3]{\\overline{R} }\\\\ & =\\dfrac{-\\sqrt[3]{R}-\\sqrt[3]{\\overline{R} }}{2} +\\dfrac{\\sqrt{3}( \\sqrt[3]{R} - \\sqrt[3]{\\overline{R} }) }{2} i\\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\&+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}$$

$$\\begin{aligned} \\\\t_3&= \\overline{\u03c9}\\cdotp \\sqrt[3]{R}+ \u03c9\\cdotp \\sqrt[3]{\\overline{R}}\\\\ & =\\dfrac{-\\sqrt[3]{R}-\\sqrt[3]{\\overline{R} }}{2} +\\dfrac{\\sqrt{3}(- \\sqrt[3]{R} + \\sqrt[3]{\\overline{R} }) }{2}i \\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\&-\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}$$

Roots of the general cubic equation

Since $$x = t - \\dfrac{b}{3a}$$, substituting the values of $$t$$, $$a$$ and $$b$$ gives

$$x_1 = t_1-\\dfrac{2}{3}$$

$$x_2 = t_2-\\dfrac{2}{3}$$

$$x_3 = t_3-\\dfrac{2}{3}$$

5. Summary

In summary, we have tried the method of cubic root formula to explore the solutions of the equation. The cubic equation $$x\u00b3 + 2x\u00b2 + 8x + 1=0$$ is found to have one real root and two complex roots. Exact values and approximations are given below.

$$\\begin{cases} x_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}-\\dfrac{2}{3} \\\\ x_2=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\\\ x_3=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)-\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\end{cases}$$

in decimal notation,

$$\\begin{cases} x_1=-0.12888523007843 \\\\ x_2=-0.93555738496079+2.6236564793854i \\\\ x_3=-0.93555738496079-2.6236564793854i \\end{cases}$$

6. Graph for the function $$f(x) = x\u00b3 + 2x\u00b2 + 8x + 1$$

Since the discriminat is greater than zero, the curve of the cubic function $$f(x) = x\u00b3 + 2x\u00b2 + 8x + 1$$ has one intersection point with the x-axis.

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\n\n\n"} +{"url": "https://uniteasy.com/solver/cubicequation/x%5E3%2B2x%5E2%2B8x%2B1%3D0/", "content": "# Solve the cubic equation:\n\n$$\nx^3+2x^2+8x+1=0\n$$\n\nQuick Answer\n\nSince the discriminant\n\n$$\n\\Delta >0\n$$\n\n, the cubic equation has one real root and two conjugate complex roots.\n\n$$\n\\Delta=14.472222222222\n$$\n\n$$\n\\begin{cases} x_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}-\\dfrac{2}{3} \\\\ x_2=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\\\ x_3=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)-\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\end{cases}\n$$\n\nIn decimals,\n\n$$\n\\begin{cases} x_1=-0.12888523007843 \\\\ x_2=-0.93555738496079+2.6236564793854i \\\\ x_3=-0.93555738496079-2.6236564793854i \\end{cases}\n$$\n\nDetailed Steps on Solution\n\n## 1. Convert to depressed cubic equation\n\nThe idea is to convert general form of cubic equation\n\n$$\nax^3+bx^2+cx+d = 0\n$$\n\nto the form without quadratic term.\n\n$$\nt^3+pt+q = 0\n$$\n\nBy substituting\n\n$$\nx\n$$\n\nwith\n\n$$\nt - \\dfrac{b}{3a}\n$$\n\n, the general cubic equation could be transformed to\n\n$$\nt^3+\\dfrac{3ac-b^2}{3a^2}t+\\dfrac{2b^3-9abc+27a^2d}{27a^3} = 0\n$$\n\nCompare with the depressed cubic equation. Then,\n\n$$\np = \\dfrac{3ac-b^2}{3a^2}\n$$\n\n$$\nq = \\dfrac{2b^3-9abc+27a^2d}{27a^3}\n$$\n\nSubstitute the values of coefficients,\n\n$$\np, q\n$$\n\nis obtained as\n\n$$\np = \\dfrac{3\\cdot 1\\cdot 8-2^2}{3\\cdot 1^2}=\\dfrac{20}{3}\n$$\n\n$$\nq = \\dfrac{2\\cdot 2^3-9\\cdot1\\cdot 2\\cdot 8+27\\cdot 1^2\\cdot1}{27\\cdot 1^3}=-\\dfrac{101}{27}\n$$\n\n### Use the substitution to transform\n\nLet\n\n$$\np\n$$\n\nand\n\n$$\nq\n$$\n\nbeing the coefficient of the linean and constant terms, the depressed cubic equation is expressed as.\n\n$$\nt^3 +pt+q=0\n$$\n\nLet\n\n$$\nx=t-\\dfrac{2}{3}\n$$\n\nThe cubic equation\n\n$$\nx³ + 2x² + 8x + 1=0\n$$\n\nis transformed to\n\n$$\nt^3 +\\dfrac{20}{3}t-\\dfrac{101}{27}=0\n$$\n\n## 2. Cardano's solution\n\nLet\n\n$$\nt=u-v\n$$\n\nCube both sides and extract common factor from two middle terms after expanding the bracket.\n\n$$\n\\begin{aligned} \\\\t^3&=(u-v)^3\\\\ & =u^3-3u^2v+3uv^2-v^3\\\\ & =-3uv(u-v)+u^3-v^3\\\\ \\end{aligned}\n$$\n\nSince\n\n$$\nu-v=t\n$$\n\n, substitution gives a linear term for the equation. Rearrange terms.\n\n$$\nx^3+3uvx-u^3+v^3=0\n$$\n\nCompare the cubic equation with the original one (1)\n\n$$\n\\begin{cases} 3uv=\\dfrac{20}{3}\\quad\\text{or}\\quad v=\\dfrac{20}{9u}\\\\ v^3-u^3=-\\dfrac{101}{27}\\\\ \\end{cases}\n$$\n\n$$\nv=\\dfrac{20}{9u}\n$$\n\ngives relationship between the two variables. Substitute the value of\n\n$$\nv\n$$\n\nto the second equation\n\n$$\n\\Big(\\dfrac{20}{9u}\\Big)^3-u^3=-\\dfrac{101}{27}\n$$\n\nSimplifying gives,\n\n$$\nu^3-\\dfrac{8000}{729}\\dfrac{1}{u^3}-\\dfrac{101}{27}=0\n$$\n\n2\n\nLet\n\n$$\nm=u^3\n$$\n\n, then the equation is transformed to a quadratic equation in terms of\n\n$$\nm\n$$\n\n. Once the value of\n\n$$\nm\n$$\n\nis determined,\n\n$$\nv^3\n$$\n\ncould be determined by\n\n$$\nv^3=-\\dfrac{101}{27}+u^3\n$$\n\n.\n\n$$\nm^2-\\dfrac{101}{27}m-\\dfrac{8000}{729}=0\n$$\n\nSovling the quadratic euqation will give two roots (some may be equal). Here we only cosider one case with positive sign before the square root radical since the negative case will produce the same result.\n\n$$\n\\begin{aligned} \\\\u^3=m&=\\dfrac{101}{54}+\\dfrac{1}{2}\\sqrt{\\Big(-\\dfrac{101}{27}^2\\Big)-4\\cdot \\Big(-\\dfrac{8000}{729}\\Big)}\\\\ & =\\dfrac{101}{54}+\\dfrac{1}{2}\\sqrt{\\dfrac{10201}{729}+\\dfrac{32000}{729}}\\\\ & =\\dfrac{101}{54}+\\dfrac{1}{2}\\sqrt{\\dfrac{521}{9}}\\\\ & =\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\\\ \\end{aligned}\n$$\n\n$$\nv^3\n$$\n\ncan be determined by the equation we deduced\n\n$$\nv^3-u^3=-\\dfrac{101}{27}\n$$\n\n. Then,\n\n$$\n\\begin{aligned} \\\\v^3&=-\\dfrac{101}{27}+u^3\\\\ & =-\\dfrac{101}{27}+\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\\\ & =-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\\\ \\end{aligned}\n$$\n\nNow we have,\n\n$$\nu^3=\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\n$$\n\nand\n\n$$\nv^3=-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\n$$\n\nEvaluating the simplest cubic equation\n\n$$\nx^3-A=0\n$$\n\n, it has 3 roots, in which the first root is a real number . The second and third are expressed in the product of cubic root of unity and the first one.\n\nIf\n\n$$\nω = \\dfrac{-1+i\\sqrt{3}}{2}\n$$\n\n, then its reciprocal is equal to its conjugate,\n\n$$\n\\dfrac{1}{ω}=\\overline{ω}\n$$\n\n.\n\n$$\n\\begin{cases} r_1=\\sqrt[3]{A}\\\\ r_2=\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{A}\\\\ r_3=\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{A}\\\\ \\end{cases}\n$$\n\nSimilary, taking cubic root for\n\n$$\nu^3\n$$\n\nand\n\n$$\nv^3\n$$\n\nalso gives 3 roots.\n\n$$\n\\begin{cases} u_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ u_2=\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ u_3=\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{cases}\n$$\n\nFor\n\n$$\nv_2\n$$\n\nand\n\n$$\nv_3\n$$\n\n, the complex numbers before radicals are the conjugates of those for\n\n$$\nu_2\n$$\n\nand\n\n$$\nu_3\n$$\n\n, which can be verified by the reciprocal property of the cubic root of unity from the equation\n\n$$\nv=\\dfrac{20}{9u}\n$$\n\n. The radicand can be taken as the negative conjugate of that in\n\n$$\nu_1\n$$\n\n,\n\n$$\nu_2\n$$\n\nand\n\n$$\nu_3\n$$\n\n, which is the same in value.\n\n$$\n\\begin{cases} v_1=\\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ v_2=\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ v_3=\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{cases}\n$$\n\nVerification for the redicand in\n\n$$\nv\n$$\n\n.\n\n$$\n\\begin{aligned} \\\\v_1&=\\dfrac{20}{9u_1}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{1}{\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{1}{\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\Big(\\dfrac{101}{54}\\Big)^2-\\Big(\\dfrac{\\sqrt{521}}{6}\\Big)^2}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\dfrac{10201}{2916}-\\dfrac{521}{36}}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\dfrac{-1\\cdot 20^3}{9^3}}}\\\\ & =-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{aligned}\n$$\n\nSince\n\n$$\nx=u-v\n$$\n\n, combining the real and imaginary parts gives 3 results for\n\n$$\nt\n$$\n\n$$\n\\begin{aligned} \\\\t_1&=u_1-v_1\\\\ & =\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{aligned}\n$$\n\n$$\n\\begin{aligned} \\\\t_2&=u_2-v_2\\\\ & =\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\Big(\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}\n$$\n\n$$\n\\begin{aligned} \\\\t_3&=u_3-v_3\\\\ & =\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\Big(\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}\n$$\n\n## 3. Vieta's Substitution\n\nIn Cardano' solution,\n\n$$\nt\n$$\n\nis defined as the difference of\n\n$$\nu\n$$\n\nand\n\n$$\nv\n$$\n\n. If we substitute the value of\n\n$$\nv\n$$\n\n(4) into (2), we get the equation.\n\n$$\nt=u-\\dfrac{20}{9u}\n$$\n\n. And then substitute the equation to the cubic equation\n\n$$\nt^3+\\dfrac{20}{3}t-\\dfrac{101}{27}=0\n$$\n\n. This method is called Vieta's Substitution for solving a cubic equation, which simplied the Cardano' solution. The substitution expression can be obtained by the following formula directly.\n\n$$\nt=u-\\dfrac{p}{3u}\n$$\n\nSubstitute the expression\n\n$$\nt=u-\\dfrac{20}{9u}\n$$\n\nto the cubic equation\n\n$$\n\\Big(u-\\dfrac{20}{9u}\\Big)^3+\\dfrac{20}{3}\\Big(u-\\dfrac{20}{9u}\\Big)-\\dfrac{101}{27}=0\n$$\n\nExpand brackets and cancel the like terms\n\n$$\nu^3-\\cancel{\\dfrac{20}{3}u^2\\dfrac{1}{u}}+\\cancel{\\dfrac{400}{27}u\\dfrac{1}{u^2}}-\\dfrac{8000}{729}\\dfrac{1}{u^3}+\\cancel{\\dfrac{20}{3}u}-\\cancel{\\dfrac{400}{27}\\dfrac{1}{u}}-\\dfrac{101}{27}=0\n$$\n\nThen we get the same equation as (2)\n\n$$\nu^3-\\dfrac{8000}{729}\\dfrac{1}{u^3}-\\dfrac{101}{27}=0\n$$\n\nThe rest of the steps will be the same as those of Cardano's solution\n\n## 4. Euler's Solution\n\n$$\nt^3+\\dfrac{20}{3}t-\\dfrac{101}{27}=0\n$$\n\nMove the linear term and constant of (1) to its right hand side. We get the following form of the equation.\n\n$$\nt^3=-\\dfrac{20}{3}t+\\dfrac{101}{27}\n$$\n\n3\n\nLet the root of the cubic equation be the sum of two cubic roots\n\n$$\nt=\\sqrt[3]{r_1}+\\sqrt[3]{r_2}\n$$\n\n4\n\nin which\n\n$$\nr_1\n$$\n\nand\n\n$$\nr_2\n$$\n\nare two roots of a quadratic equation\n\n$$\nz^2-\\alpha z+ β=0\n$$\n\n5\n\nUsing Vieta's Formula, the following equations are established.\n\n$$\nr_1+r_2 = \\alpha \\quad \\text{and} \\quad r_1r_2 = β\n$$\n\nTo determine\n\n$$\n\\alpha\n$$\n\n,\n\n$$\nβ\n$$\n\n, cube both sides of the equation (4)\n\n$$\nt^3=3\\sqrt[3]{r_1r_2}(\\sqrt[3]{r_1}+\\sqrt[3]{r_2})+r_1+r_2\n$$\n\nSubstituting, the equation is simplified to\n\n$$\nt^3=3\\sqrt[3]{β}t+\\alpha\n$$\n\nCompare the cubic equation with (3), the following equations are established\n\n$$\n\\begin{cases} 3\\sqrt[3]{β}=-\\dfrac{20}{3}\\\\ \\alpha=\\dfrac{101}{27}\\\\ \\end{cases}\n$$\n\nSolving for\n\n$$\nβ\n$$\n\ngives\n\n$$\nβ=-\\dfrac{8000}{729}\n$$\n\nSo the quadratic equation (5) is determined as\n\n$$\nz^2-\\dfrac{101}{27}z-\\dfrac{8000}{729}=0\n$$\n\n6\n\nSolving the quadratic equation yields\n\n$$\n\\begin{cases} r_1=\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\approx5.6746077738748\\\\ r_2=\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}\\approx-1.9338670331341\\\\ \\end{cases}\n$$\n\nTherefore, one of the roots of the cubic equation could be obtained from (4).\n\n$$\nt_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\n$$\n\nin decimals,\n\n$$\nt_1=0.53778143658824\n$$\n\nHowever, since the cube root of a quantity has triple values,\n\nThe other two roots could be determined as,\n\n$$\nt_2=\\dfrac{-1+i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\dfrac{-1-i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\n$$\n\n$$\nt_3=\\dfrac{-1-i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\dfrac{-1+i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\n$$\n\nCombining the real and imaginary parts results in the same result as that obtained by Cardano's solution.\n\nFor the equation\n\n$$\nt^3 +\\dfrac{20}{3}t-\\dfrac{101}{27}\n$$\n\n, we have\n\n$$\np=\\dfrac{20}{3}\n$$\n\nand\n\n$$\nq = -\\dfrac{101}{27}\n$$\n\n### Calculate the discriminant\n\nThe nature of the roots are determined by the sign of the discriminant.\n\n$$\n\\begin{aligned} \\\\\\Delta&=\\dfrac{q^2}{4}+\\dfrac{p^3}{27}\\\\ & =\\dfrac{\\Big(-\\dfrac{101}{27}\\Big)^2}{4}+\\dfrac{\\Big(\\dfrac{20}{3}\\Big)^3}{27}\\\\ & =\\dfrac{10201}{2916}+\\dfrac{8000}{729}\\\\ & =\\dfrac{10201\\cdot 1+8000\\cdot 4}{2916}\\\\ & =14.472222222222\\\\ \\end{aligned}\n$$\n\n### 4.1 Use the root formula directly\n\nIf the discriminant is greater than zero, we can use the root formula to determine the roots of the cubic equation.\n\n$$\nt_{1,2,3} =\\begin{cases} \\sqrt[3]{-\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} } } +\\sqrt[3]{-\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }}& \\\\ ω\\cdotp \\sqrt[3]{-\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} } } + \\overline{ω} \\sqrt[3]{-\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }}&\\ \\\\ \\overline{ω}\\cdotp \\sqrt[3]{-\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} } } + ω\\cdotp \\sqrt[3]{-\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }} \\end{cases}\n$$\n\nin which,\n\n$$\nω = \\dfrac{-1+i\\sqrt{3}}{2}\n$$\n\nand\n\n$$\n\\overline{ω} =\\dfrac{-1-i\\sqrt{3}}{2}\n$$\n\nSubstitute the values of\n\n$$\np, q\n$$\n\nand\n\n$$\n\\Delta\n$$\n\nwhich we have calculated. Then,\n\n$$\n\\begin{aligned} \\\\t_1&=\\sqrt[3]{\\dfrac{101}{54}+\\sqrt{\\dfrac{42201}{2916}}}+\\sqrt[3]{\\dfrac{101}{54}-\\sqrt{\\dfrac{42201}{2916}}}\\\\ & =\\sqrt[3]{\\dfrac{101}{54}+\\sqrt{\\dfrac{521\\cdot\\cancel{81}}{36\\cdot\\cancel{81}}}}+\\sqrt[3]{\\dfrac{101}{54}-\\sqrt{\\dfrac{521\\cdot\\cancel{81}}{36\\cdot\\cancel{81}}}}\\\\ & =\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{aligned}\n$$\n\nIf we denote\n\n$$\nR = -\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }\n$$\n\n$$\n\\overline{R} = -\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }\n$$\n\nthen,\n\n$$\n\\sqrt[3]{R} = \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\n$$\n\n,\n\n$$\n\\sqrt[3]{\\overline{R}} =\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\n$$\n\n$$\n\\begin{aligned} \\\\t_2&= ω\\cdotp \\sqrt[3]{R}+ \\overline{ω} \\sqrt[3]{\\overline{R} }\\\\ & =\\dfrac{-\\sqrt[3]{R}-\\sqrt[3]{\\overline{R} }}{2} +\\dfrac{\\sqrt{3}( \\sqrt[3]{R} - \\sqrt[3]{\\overline{R} }) }{2} i\\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\&+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}\n$$\n\n$$\n\\begin{aligned} \\\\t_3&= \\overline{ω}\\cdotp \\sqrt[3]{R}+ ω\\cdotp \\sqrt[3]{\\overline{R}}\\\\ & =\\dfrac{-\\sqrt[3]{R}-\\sqrt[3]{\\overline{R} }}{2} +\\dfrac{\\sqrt{3}(- \\sqrt[3]{R} + \\sqrt[3]{\\overline{R} }) }{2}i \\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\&-\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}\n$$\n\n## Roots of the general cubic equation\n\nSince\n\n$$\nx = t - \\dfrac{b}{3a}\n$$\n\n, substituting the values of\n\n$$\nt\n$$\n\n,\n\n$$\na\n$$\n\nand\n\n$$\nb\n$$\n\ngives\n\n$$\nx_1 = t_1-\\dfrac{2}{3}\n$$\n\n$$\nx_2 = t_2-\\dfrac{2}{3}\n$$\n\n$$\nx_3 = t_3-\\dfrac{2}{3}\n$$\n\n## 5. Summary\n\nIn summary, we have tried the method of cubic root formula to explore the solutions of the equation. The cubic equation\n\n$$\nx³ + 2x² + 8x + 1=0\n$$\n\nis found to have one real root and two complex roots. Exact values and approximations are given below.\n\n$$\n\\begin{cases} x_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}-\\dfrac{2}{3} \\\\ x_2=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\\\ x_3=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)-\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\end{cases}\n$$\n\nin decimal notation,\n\n$$\n\\begin{cases} x_1=-0.12888523007843 \\\\ x_2=-0.93555738496079+2.6236564793854i \\\\ x_3=-0.93555738496079-2.6236564793854i \\end{cases}\n$$\n\n## 6. Graph for the function\n\n$$\nf(x) = x³ + 2x² + 8x + 1\n$$\n\nSince the discriminat is greater than zero, the curve of the cubic function\n\n$$\nf(x) = x³ + 2x² + 8x + 1\n$$\n\nhas one intersection point with the x-axis.\n\n## More cubic equations\n", "main_html": "
\n
\n

Solve the cubic equation:

\n

$$x^3+2x^2+8x+1=0 $$

\n

Quick Answer

\n

Since the discriminant $$\\Delta >0$$, the cubic equation has one real root and two conjugate complex roots.

$$ \\Delta=14.472222222222$$

$$\\begin{cases} x_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}-\\dfrac{2}{3} \\\\ x_2=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\\\ x_3=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)-\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\end{cases}$$

In decimals,

$$\\begin{cases} x_1=-0.12888523007843 \\\\ x_2=-0.93555738496079+2.6236564793854i \\\\ x_3=-0.93555738496079-2.6236564793854i \\end{cases}$$

Detailed Steps on Solution

1. Convert to depressed cubic equation

The idea is to convert general form of cubic equation

$$ax^3+bx^2+cx+d = 0$$

to the form without quadratic term.

$$t^3+pt+q = 0$$

By substituting $$x$$ with $$t - \\dfrac{b}{3a}$$, the general cubic equation could be transformed to

$$t^3+\\dfrac{3ac-b^2}{3a^2}t+\\dfrac{2b^3-9abc+27a^2d}{27a^3} = 0 $$

Compare with the depressed cubic equation. Then,

$$p = \\dfrac{3ac-b^2}{3a^2}$$

$$q = \\dfrac{2b^3-9abc+27a^2d}{27a^3} $$

Substitute the values of coefficients, $$p, q$$ is obtained as

$$p = \\dfrac{3\\cdot 1\\cdot 8-2^2}{3\\cdot 1^2}=\\dfrac{20}{3}$$

$$q = \\dfrac{2\\cdot 2^3-9\\cdot1\\cdot 2\\cdot 8+27\\cdot 1^2\\cdot1}{27\\cdot 1^3}=-\\dfrac{101}{27}$$

Use the substitution to transform

Let $$p$$ and $$q$$ being the coefficient of the linean and constant terms, the depressed cubic equation is expressed as.

$$t^3 +pt+q=0$$

Let $$x=t-\\dfrac{2}{3}$$

The cubic equation $$x³ + 2x² + 8x + 1=0$$ is transformed to

$$t^3 +\\dfrac{20}{3}t-\\dfrac{101}{27}=0$$

2. Cardano's solution

Let $$t=u-v$$

Cube both sides and extract common factor from two middle terms after expanding the bracket.

$$\\begin{aligned} \\\\t^3&=(u-v)^3\\\\ & =u^3-3u^2v+3uv^2-v^3\\\\ & =-3uv(u-v)+u^3-v^3\\\\ \\end{aligned}$$

Since $$u-v=t$$, substitution gives a linear term for the equation.\n Rearrange terms.

$$x^3+3uvx-u^3+v^3=0$$

Compare the cubic equation with the original one (1)

$$\\begin{cases} 3uv=\\dfrac{20}{3}\\quad\\text{or}\\quad v=\\dfrac{20}{9u}\\\\ v^3-u^3=-\\dfrac{101}{27}\\\\ \\end{cases}$$

$$v=\\dfrac{20}{9u}$$ gives relationship between the two variables. Substitute the value of $$v$$ to the second equation

$$\\Big(\\dfrac{20}{9u}\\Big)^3-u^3=-\\dfrac{101}{27}$$

Simplifying gives,

$$u^3-\\dfrac{8000}{729}\\dfrac{1}{u^3}-\\dfrac{101}{27}=0$$2

Let $$m=u^3$$, then the equation is transformed to a quadratic equation in terms of $$m$$.\n Once the value of $$m$$ is determined, $$v^3$$ could be determined by $$v^3=-\\dfrac{101}{27}+u^3$$.

$$m^2-\\dfrac{101}{27}m-\\dfrac{8000}{729}=0$$

Sovling the quadratic euqation will give two roots (some may be equal). Here we only cosider\n one case with positive sign before the square root radical since the negative case will produce the same result.

$$\\begin{aligned} \\\\u^3=m&=\\dfrac{101}{54}+\\dfrac{1}{2}\\sqrt{\\Big(-\\dfrac{101}{27}^2\\Big)-4\\cdot \\Big(-\\dfrac{8000}{729}\\Big)}\\\\ & =\\dfrac{101}{54}+\\dfrac{1}{2}\\sqrt{\\dfrac{10201}{729}+\\dfrac{32000}{729}}\\\\ & =\\dfrac{101}{54}+\\dfrac{1}{2}\\sqrt{\\dfrac{521}{9}}\\\\ & =\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\\\ \\end{aligned}$$

$$v^3$$ can be determined by the equation we deduced $$v^3-u^3=-\\dfrac{101}{27}$$. Then,

$$\\begin{aligned} \\\\v^3&=-\\dfrac{101}{27}+u^3\\\\ & =-\\dfrac{101}{27}+\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\\\ & =-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\\\ \\end{aligned}$$

Now we have,

$$u^3=\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}$$ and $$v^3=-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}$$

Evaluating the simplest cubic equation $$x^3-A=0$$,\n it has 3 roots, in which the first root is a real number . The second and third are\n expressed in the product of cubic root of unity and the first one.

If $$ω = \\dfrac{-1+i\\sqrt{3}}{2}$$, then its reciprocal is equal to its conjugate, $$\\dfrac{1}{ω}=\\overline{ω}$$.

$$\\begin{cases} r_1=\\sqrt[3]{A}\\\\ r_2=\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{A}\\\\ r_3=\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{A}\\\\ \\end{cases}$$

Similary, taking cubic root for $$u^3$$ and $$v^3$$ also gives 3 roots.

$$\\begin{cases} u_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ u_2=\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ u_3=\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{cases}$$

For $$v_2$$ and $$v_3$$, the complex numbers before radicals are the conjugates of\n those for $$u_2$$ and $$u_3$$, which can be verified by the reciprocal property\n of the cubic root of unity from the equation $$v=\\dfrac{20}{9u}$$. The radicand can be taken as the\n negative conjugate of that in $$u_1$$, $$u_2$$ and $$u_3$$, which is the same in value.

$$\\begin{cases} v_1=\\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ v_2=\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ v_3=\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{cases}$$

Verification for the redicand in $$v$$.

$$\\begin{aligned} \\\\v_1&=\\dfrac{20}{9u_1}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{1}{\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{1}{\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\Big(\\dfrac{101}{54}\\Big)^2-\\Big(\\dfrac{\\sqrt{521}}{6}\\Big)^2}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\dfrac{10201}{2916}-\\dfrac{521}{36}}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\dfrac{-1\\cdot 20^3}{9^3}}}\\\\ & =-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{aligned}$$

Since $$x=u-v$$, combining the real and imaginary parts gives\n 3 results for $$t$$

$$\\begin{aligned} \\\\t_1&=u_1-v_1\\\\ & =\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{aligned}$$

$$\\begin{aligned} \\\\t_2&=u_2-v_2\\\\ & =\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\Big(\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}$$

$$\\begin{aligned} \\\\t_3&=u_3-v_3\\\\ & =\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\Big(\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}$$

3. Vieta's Substitution

In Cardano' solution, $$t$$ is defined as the difference of $$u$$ and\n $$v$$. If we substitute the value of $$v$$ (4) into (2), we get the\n equation. $$t=u-\\dfrac{20}{9u}$$. And then substitute the equation to the cubic equation\n $$t^3+\\dfrac{20}{3}t-\\dfrac{101}{27}=0$$. This method is called Vieta's Substitution\n for solving a cubic equation, which simplied the Cardano' solution. The substitution\n expression can be obtained by the following formula directly.

$$t=u-\\dfrac{p}{3u}$$

Substitute the expression $$t=u-\\dfrac{20}{9u}$$ to the cubic equation

$$\\Big(u-\\dfrac{20}{9u}\\Big)^3+\\dfrac{20}{3}\\Big(u-\\dfrac{20}{9u}\\Big)-\\dfrac{101}{27}=0$$

Expand brackets and cancel the like terms

$$u^3-\\cancel{\\dfrac{20}{3}u^2\\dfrac{1}{u}}+\\cancel{\\dfrac{400}{27}u\\dfrac{1}{u^2}}-\\dfrac{8000}{729}\\dfrac{1}{u^3}+\\cancel{\\dfrac{20}{3}u}-\\cancel{\\dfrac{400}{27}\\dfrac{1}{u}}-\\dfrac{101}{27}=0$$

Then we get the same equation as (2)

$$u^3-\\dfrac{8000}{729}\\dfrac{1}{u^3}-\\dfrac{101}{27}=0$$

The rest of the steps will be the same as those of Cardano's solution

4. Euler's Solution

$$t^3+\\dfrac{20}{3}t-\\dfrac{101}{27}=0$$

Move the linear term and constant of (1) to its right hand side.\n We get the following form of the equation.

$$t^3=-\\dfrac{20}{3}t+\\dfrac{101}{27} $$3

Let the root of the cubic equation be the sum of two cubic roots

$$t=\\sqrt[3]{r_1}+\\sqrt[3]{r_2} $$4

in which $$r_1$$ and $$r_2$$ are two roots of a quadratic equation

$$z^2-\\alpha z+ β=0 $$5

Using Vieta's Formula, the following equations are established.

$$r_1+r_2 = \\alpha \\quad \\text{and} \\quad r_1r_2 = β $$

To determine $$\\alpha$$, $$β$$, cube both sides of the equation (4)

$$t^3=3\\sqrt[3]{r_1r_2}(\\sqrt[3]{r_1}+\\sqrt[3]{r_2})+r_1+r_2 $$

Substituting, the equation is simplified to

$$t^3=3\\sqrt[3]{β}t+\\alpha $$

Compare the cubic equation with (3), the following equations are established

$$\\begin{cases} 3\\sqrt[3]{β}=-\\dfrac{20}{3}\\\\ \\alpha=\\dfrac{101}{27}\\\\ \\end{cases}$$

Solving for $$β$$ gives

$$β=-\\dfrac{8000}{729} $$

So the quadratic equation (5) is determined as

$$z^2-\\dfrac{101}{27}z-\\dfrac{8000}{729}=0$$6

Solving the quadratic equation yields

$$\\begin{cases} r_1=\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\approx5.6746077738748\\\\ r_2=\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}\\approx-1.9338670331341\\\\ \\end{cases}$$

Therefore, one of the roots of the cubic equation could be obtained from (4).

$$t_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}} $$

in decimals,

$$t_1=0.53778143658824 $$

However, since the cube root of a quantity has triple values,

The other two roots could be determined as,

$$t_2=\\dfrac{-1+i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\dfrac{-1-i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}} $$

$$t_3=\\dfrac{-1-i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\dfrac{-1+i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}} $$

Combining the real and imaginary parts\n results in the same result as that obtained by Cardano's solution.

For the equation $$t^3 +\\dfrac{20}{3}t-\\dfrac{101}{27}$$, we have $$p=\\dfrac{20}{3}$$ and $$q = -\\dfrac{101}{27}$$

Calculate the discriminant

The nature of the roots are determined by the sign of the discriminant.

$$\\begin{aligned} \\\\\\Delta&=\\dfrac{q^2}{4}+\\dfrac{p^3}{27}\\\\ & =\\dfrac{\\Big(-\\dfrac{101}{27}\\Big)^2}{4}+\\dfrac{\\Big(\\dfrac{20}{3}\\Big)^3}{27}\\\\ & =\\dfrac{10201}{2916}+\\dfrac{8000}{729}\\\\ & =\\dfrac{10201\\cdot 1+8000\\cdot 4}{2916}\\\\ & =14.472222222222\\\\ \\end{aligned}$$

4.1 Use the root formula directly

If the discriminant is greater than zero, we can use the root formula to determine the roots of the cubic equation.

$$t_{1,2,3} =\\begin{cases} \\sqrt[3]{-\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} } } +\\sqrt[3]{-\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }}& \\\\ ω\\cdotp \\sqrt[3]{-\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} } } + \\overline{ω} \\sqrt[3]{-\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }}&\\ \\\\ \\overline{ω}\\cdotp \\sqrt[3]{-\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} } } + ω\\cdotp \\sqrt[3]{-\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }} \\end{cases}$$

in which, $$ ω = \\dfrac{-1+i\\sqrt{3}}{2} $$ and $$ \\overline{ω} =\\dfrac{-1-i\\sqrt{3}}{2}$$

Substitute the values of $$p, q$$ and $$\\Delta$$ which we have calculated. Then,

$$\\begin{aligned} \\\\t_1&=\\sqrt[3]{\\dfrac{101}{54}+\\sqrt{\\dfrac{42201}{2916}}}+\\sqrt[3]{\\dfrac{101}{54}-\\sqrt{\\dfrac{42201}{2916}}}\\\\ & =\\sqrt[3]{\\dfrac{101}{54}+\\sqrt{\\dfrac{521\\cdot\\cancel{81}}{36\\cdot\\cancel{81}}}}+\\sqrt[3]{\\dfrac{101}{54}-\\sqrt{\\dfrac{521\\cdot\\cancel{81}}{36\\cdot\\cancel{81}}}}\\\\ & =\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{aligned}$$

If we denote

$$R = -\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }$$

$$\\overline{R} = -\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }$$

then,

$$\\sqrt[3]{R} = \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}$$, $$\\sqrt[3]{\\overline{R}} =\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}$$

$$\\begin{aligned} \\\\t_2&= ω\\cdotp \\sqrt[3]{R}+ \\overline{ω} \\sqrt[3]{\\overline{R} }\\\\ & =\\dfrac{-\\sqrt[3]{R}-\\sqrt[3]{\\overline{R} }}{2} +\\dfrac{\\sqrt{3}( \\sqrt[3]{R} - \\sqrt[3]{\\overline{R} }) }{2} i\\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\&+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}$$

$$\\begin{aligned} \\\\t_3&= \\overline{ω}\\cdotp \\sqrt[3]{R}+ ω\\cdotp \\sqrt[3]{\\overline{R}}\\\\ & =\\dfrac{-\\sqrt[3]{R}-\\sqrt[3]{\\overline{R} }}{2} +\\dfrac{\\sqrt{3}(- \\sqrt[3]{R} + \\sqrt[3]{\\overline{R} }) }{2}i \\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\&-\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}$$

Roots of the general cubic equation

Since $$x = t - \\dfrac{b}{3a}$$, substituting the values of $$t$$, $$a$$ and $$b$$ gives

$$x_1 = t_1-\\dfrac{2}{3}$$

$$x_2 = t_2-\\dfrac{2}{3}$$

$$x_3 = t_3-\\dfrac{2}{3}$$

5. Summary

In summary, we have tried the method of cubic root formula to explore the solutions of the equation. The cubic equation $$x³ + 2x² + 8x + 1=0$$ is found to have one real root and two complex roots. Exact values and approximations are given below.

$$\\begin{cases} x_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}-\\dfrac{2}{3} \\\\ x_2=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\\\ x_3=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)-\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\end{cases}$$

in decimal notation,

$$\\begin{cases} x_1=-0.12888523007843 \\\\ x_2=-0.93555738496079+2.6236564793854i \\\\ x_3=-0.93555738496079-2.6236564793854i \\end{cases}$$

6. Graph for the function $$f(x) = x³ + 2x² + 8x + 1$$

Since the discriminat is greater than zero, the curve of the cubic function $$f(x) = x³ + 2x² + 8x + 1$$ has one intersection point with the x-axis.

\n\n\n\n\n\n\n
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More cubic equations

\n\n
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\n", "content_list": [[{"type": "title", "raw_content": "

Solve the cubic equation:

", "content": {"title_content": "Solve the cubic equation:", "level": "1"}}, {"type": "equation-interline", "raw_content": "

$$x^3+2x^2+8x+1=0 $$

", "content": {"math_content": "x^3+2x^2+8x+1=0", "math_type": "latex", "by": "mathjax_mock"}}, {"type": "paragraph", "raw_content": "

Quick Answer

", "content": [{"c": "Quick Answer", "t": "text"}]}, {"type": "paragraph", "raw_content": "

Since the discriminant

", "content": [{"c": "Since the discriminant", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$\\Delta >0$$

", "content": {"math_content": "\\Delta >0", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

, the cubic equation has one real root and two conjugate complex roots.

", "content": [{"c": ", the cubic equation has one real root and two conjugate complex roots.", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$ \\Delta=14.472222222222$$

", "content": {"math_content": "\\Delta=14.472222222222", "math_type": "latex", "by": "katex"}}, {"type": "equation-interline", "raw_content": "

$$\\begin{cases} x_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}-\\dfrac{2}{3} \\\\ x_2=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\\\ x_3=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)-\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\end{cases}$$

", "content": {"math_content": "\\begin{cases} x_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}-\\dfrac{2}{3} \\\\ x_2=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\\\ x_3=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)-\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\end{cases}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

In decimals,

", "content": [{"c": "In decimals,", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$\\begin{cases} x_1=-0.12888523007843 \\\\ x_2=-0.93555738496079+2.6236564793854i \\\\ x_3=-0.93555738496079-2.6236564793854i \\end{cases}$$

", "content": {"math_content": "\\begin{cases} x_1=-0.12888523007843 \\\\ x_2=-0.93555738496079+2.6236564793854i \\\\ x_3=-0.93555738496079-2.6236564793854i \\end{cases}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Detailed Steps on Solution

", "content": [{"c": "Detailed Steps on Solution", "t": "text"}]}, {"type": "title", "raw_content": "

1. Convert to depressed cubic equation

", "content": {"title_content": "1. Convert to depressed cubic equation", "level": "2"}}, {"type": "paragraph", "raw_content": "

The idea is to convert general form of cubic equation

", "content": [{"c": "The idea is to convert general form of cubic equation", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$ax^3+bx^2+cx+d = 0$$

", "content": {"math_content": "ax^3+bx^2+cx+d = 0", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

to the form without quadratic term.

", "content": [{"c": "to the form without quadratic term.", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$t^3+pt+q = 0$$

", "content": {"math_content": "t^3+pt+q = 0", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

By substituting

", "content": [{"c": "By substituting", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$x$$

", "content": {"math_content": "x", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

with

", "content": [{"c": "with", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$t - \\dfrac{b}{3a}$$

", "content": {"math_content": "t - \\dfrac{b}{3a}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

, the general cubic equation could be transformed to

", "content": [{"c": ", the general cubic equation could be transformed to", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$t^3+\\dfrac{3ac-b^2}{3a^2}t+\\dfrac{2b^3-9abc+27a^2d}{27a^3} = 0 $$

", "content": {"math_content": "t^3+\\dfrac{3ac-b^2}{3a^2}t+\\dfrac{2b^3-9abc+27a^2d}{27a^3} = 0", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Compare with the depressed cubic equation. Then,

", "content": [{"c": "Compare with the depressed cubic equation. Then,", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$p = \\dfrac{3ac-b^2}{3a^2}$$

", "content": {"math_content": "p = \\dfrac{3ac-b^2}{3a^2}", "math_type": "latex", "by": "katex"}}, {"type": "equation-interline", "raw_content": "

$$q = \\dfrac{2b^3-9abc+27a^2d}{27a^3} $$

", "content": {"math_content": "q = \\dfrac{2b^3-9abc+27a^2d}{27a^3}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Substitute the values of coefficients,

", "content": [{"c": "Substitute the values of coefficients,", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$p, q$$

", "content": {"math_content": "p, q", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

is obtained as

", "content": [{"c": "is obtained as", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$p = \\dfrac{3\\cdot 1\\cdot 8-2^2}{3\\cdot 1^2}=\\dfrac{20}{3}$$

", "content": {"math_content": "p = \\dfrac{3\\cdot 1\\cdot 8-2^2}{3\\cdot 1^2}=\\dfrac{20}{3}", "math_type": "latex", "by": "katex"}}, {"type": "equation-interline", "raw_content": "

$$q = \\dfrac{2\\cdot 2^3-9\\cdot1\\cdot 2\\cdot 8+27\\cdot 1^2\\cdot1}{27\\cdot 1^3}=-\\dfrac{101}{27}$$

", "content": {"math_content": "q = \\dfrac{2\\cdot 2^3-9\\cdot1\\cdot 2\\cdot 8+27\\cdot 1^2\\cdot1}{27\\cdot 1^3}=-\\dfrac{101}{27}", "math_type": "latex", "by": "katex"}}, {"type": "title", "raw_content": "

Use the substitution to transform

", "content": {"title_content": "Use the substitution to transform", "level": "3"}}, {"type": "paragraph", "raw_content": "

Let

", "content": [{"c": "Let", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$p$$

", "content": {"math_content": "p", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

and

", "content": [{"c": "and", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$q$$

", "content": {"math_content": "q", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

being the coefficient of the linean and constant terms, the depressed cubic equation is expressed as.

", "content": [{"c": "being the coefficient of the linean and constant terms, the depressed cubic equation is expressed as.", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$t^3 +pt+q=0$$

", "content": {"math_content": "t^3 +pt+q=0", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Let

", "content": [{"c": "Let", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$x=t-\\dfrac{2}{3}$$

", "content": {"math_content": "x=t-\\dfrac{2}{3}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

The cubic equation

", "content": [{"c": "The cubic equation", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$x³ + 2x² + 8x + 1=0$$

", "content": {"math_content": "x³ + 2x² + 8x + 1=0", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

is transformed to

", "content": [{"c": "is transformed to", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$t^3 +\\dfrac{20}{3}t-\\dfrac{101}{27}=0$$

", "content": {"math_content": "t^3 +\\dfrac{20}{3}t-\\dfrac{101}{27}=0", "math_type": "latex", "by": "katex"}}, {"type": "title", "raw_content": "

2. Cardano's solution

", "content": {"title_content": "2. Cardano's solution", "level": "2"}}, {"type": "paragraph", "raw_content": "

Let

", "content": [{"c": "Let", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$t=u-v$$

", "content": {"math_content": "t=u-v", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Cube both sides and extract common factor from two middle terms after expanding the bracket.

", "content": [{"c": "Cube both sides and extract common factor from two middle terms after expanding the bracket.", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$\\begin{aligned} \\\\t^3&=(u-v)^3\\\\ & =u^3-3u^2v+3uv^2-v^3\\\\ & =-3uv(u-v)+u^3-v^3\\\\ \\end{aligned}$$

", "content": {"math_content": "\\begin{aligned} \\\\t^3&=(u-v)^3\\\\ & =u^3-3u^2v+3uv^2-v^3\\\\ & =-3uv(u-v)+u^3-v^3\\\\ \\end{aligned}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Since

", "content": [{"c": "Since", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$u-v=t$$

", "content": {"math_content": "u-v=t", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

, substitution gives a linear term for the equation.\n Rearrange terms.

", "content": [{"c": ", substitution gives a linear term for the equation. Rearrange terms.", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$x^3+3uvx-u^3+v^3=0$$

", "content": {"math_content": "x^3+3uvx-u^3+v^3=0", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Compare the cubic equation with the original one (1)

", "content": [{"c": "Compare the cubic equation with the original one (1)", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$\\begin{cases} 3uv=\\dfrac{20}{3}\\quad\\text{or}\\quad v=\\dfrac{20}{9u}\\\\ v^3-u^3=-\\dfrac{101}{27}\\\\ \\end{cases}$$

", "content": {"math_content": "\\begin{cases} 3uv=\\dfrac{20}{3}\\quad\\text{or}\\quad v=\\dfrac{20}{9u}\\\\ v^3-u^3=-\\dfrac{101}{27}\\\\ \\end{cases}", "math_type": "latex", "by": "katex"}}, {"type": "equation-interline", "raw_content": "

$$v=\\dfrac{20}{9u}$$

", "content": {"math_content": "v=\\dfrac{20}{9u}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

gives relationship between the two variables. Substitute the value of

", "content": [{"c": "gives relationship between the two variables. Substitute the value of", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$v$$

", "content": {"math_content": "v", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

to the second equation

", "content": [{"c": "to the second equation", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$\\Big(\\dfrac{20}{9u}\\Big)^3-u^3=-\\dfrac{101}{27}$$

", "content": {"math_content": "\\Big(\\dfrac{20}{9u}\\Big)^3-u^3=-\\dfrac{101}{27}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Simplifying gives,

", "content": [{"c": "Simplifying gives,", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$u^3-\\dfrac{8000}{729}\\dfrac{1}{u^3}-\\dfrac{101}{27}=0$$

", "content": {"math_content": "u^3-\\dfrac{8000}{729}\\dfrac{1}{u^3}-\\dfrac{101}{27}=0", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

2

", "content": [{"c": "2", "t": "text"}]}, {"type": "paragraph", "raw_content": "

Let

", "content": [{"c": "Let", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$m=u^3$$

", "content": {"math_content": "m=u^3", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

, then the equation is transformed to a quadratic equation in terms of

", "content": [{"c": ", then the equation is transformed to a quadratic equation in terms of", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$m$$

", "content": {"math_content": "m", "math_type": "latex", "by": "mathjax_mock"}}, {"type": "paragraph", "raw_content": "

.\n Once the value of

", "content": [{"c": ". Once the value of", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$m$$

", "content": {"math_content": "m", "math_type": "latex", "by": "mathjax_mock"}}, {"type": "paragraph", "raw_content": "

is determined,

", "content": [{"c": "is determined,", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$v^3$$

", "content": {"math_content": "v^3", "math_type": "latex", "by": "mathjax_mock"}}, {"type": "paragraph", "raw_content": "

could be determined by

", "content": [{"c": "could be determined by", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$v^3=-\\dfrac{101}{27}+u^3$$

", "content": {"math_content": "v^3=-\\dfrac{101}{27}+u^3", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

.

", "content": [{"c": ".", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$m^2-\\dfrac{101}{27}m-\\dfrac{8000}{729}=0$$

", "content": {"math_content": "m^2-\\dfrac{101}{27}m-\\dfrac{8000}{729}=0", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Sovling the quadratic euqation will give two roots (some may be equal). Here we only cosider\n one case with positive sign before the square root radical since the negative case will produce the same result.

", "content": [{"c": "Sovling the quadratic euqation will give two roots (some may be equal). Here we only cosider one case with positive sign before the square root radical since the negative case will produce the same result.", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$\\begin{aligned} \\\\u^3=m&=\\dfrac{101}{54}+\\dfrac{1}{2}\\sqrt{\\Big(-\\dfrac{101}{27}^2\\Big)-4\\cdot \\Big(-\\dfrac{8000}{729}\\Big)}\\\\ & =\\dfrac{101}{54}+\\dfrac{1}{2}\\sqrt{\\dfrac{10201}{729}+\\dfrac{32000}{729}}\\\\ & =\\dfrac{101}{54}+\\dfrac{1}{2}\\sqrt{\\dfrac{521}{9}}\\\\ & =\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\\\ \\end{aligned}$$

", "content": {"math_content": "\\begin{aligned} \\\\u^3=m&=\\dfrac{101}{54}+\\dfrac{1}{2}\\sqrt{\\Big(-\\dfrac{101}{27}^2\\Big)-4\\cdot \\Big(-\\dfrac{8000}{729}\\Big)}\\\\ & =\\dfrac{101}{54}+\\dfrac{1}{2}\\sqrt{\\dfrac{10201}{729}+\\dfrac{32000}{729}}\\\\ & =\\dfrac{101}{54}+\\dfrac{1}{2}\\sqrt{\\dfrac{521}{9}}\\\\ & =\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\\\ \\end{aligned}", "math_type": "latex", "by": "katex"}}, {"type": "equation-interline", "raw_content": "

$$v^3$$

", "content": {"math_content": "v^3", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

can be determined by the equation we deduced

", "content": [{"c": "can be determined by the equation we deduced", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$v^3-u^3=-\\dfrac{101}{27}$$

", "content": {"math_content": "v^3-u^3=-\\dfrac{101}{27}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

. Then,

", "content": [{"c": ". Then,", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$\\begin{aligned} \\\\v^3&=-\\dfrac{101}{27}+u^3\\\\ & =-\\dfrac{101}{27}+\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\\\ & =-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\\\ \\end{aligned}$$

", "content": {"math_content": "\\begin{aligned} \\\\v^3&=-\\dfrac{101}{27}+u^3\\\\ & =-\\dfrac{101}{27}+\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\\\ & =-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\\\ \\end{aligned}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Now we have,

", "content": [{"c": "Now we have,", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$u^3=\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}$$

", "content": {"math_content": "u^3=\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

and

", "content": [{"c": "and", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$v^3=-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}$$

", "content": {"math_content": "v^3=-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Evaluating the simplest cubic equation

", "content": [{"c": "Evaluating the simplest cubic equation", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$x^3-A=0$$

", "content": {"math_content": "x^3-A=0", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

,\n it has 3 roots, in which the first root is a real number . The second and third are\n expressed in the product of cubic root of unity and the first one.

", "content": [{"c": ", it has 3 roots, in which the first root is a real number . The second and third are expressed in the product of cubic root of unity and the first one.", "t": "text"}]}, {"type": "paragraph", "raw_content": "

If

", "content": [{"c": "If", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$ω = \\dfrac{-1+i\\sqrt{3}}{2}$$

", "content": {"math_content": "ω = \\dfrac{-1+i\\sqrt{3}}{2}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

, then its reciprocal is equal to its conjugate,

", "content": [{"c": ", then its reciprocal is equal to its conjugate,", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$\\dfrac{1}{ω}=\\overline{ω}$$

", "content": {"math_content": "\\dfrac{1}{ω}=\\overline{ω}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

.

", "content": [{"c": ".", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$\\begin{cases} r_1=\\sqrt[3]{A}\\\\ r_2=\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{A}\\\\ r_3=\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{A}\\\\ \\end{cases}$$

", "content": {"math_content": "\\begin{cases} r_1=\\sqrt[3]{A}\\\\ r_2=\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{A}\\\\ r_3=\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{A}\\\\ \\end{cases}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Similary, taking cubic root for

", "content": [{"c": "Similary, taking cubic root for", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$u^3$$

", "content": {"math_content": "u^3", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

and

", "content": [{"c": "and", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$v^3$$

", "content": {"math_content": "v^3", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

also gives 3 roots.

", "content": [{"c": "also gives 3 roots.", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$\\begin{cases} u_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ u_2=\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ u_3=\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{cases}$$

", "content": {"math_content": "\\begin{cases} u_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ u_2=\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ u_3=\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{cases}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

For

", "content": [{"c": "For", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$v_2$$

", "content": {"math_content": "v_2", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

and

", "content": [{"c": "and", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$v_3$$

", "content": {"math_content": "v_3", "math_type": "latex", "by": "mathjax_mock"}}, {"type": "paragraph", "raw_content": "

, the complex numbers before radicals are the conjugates of\n those for

", "content": [{"c": ", the complex numbers before radicals are the conjugates of those for", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$u_2$$

", "content": {"math_content": "u_2", "math_type": "latex", "by": "mathjax_mock"}}, {"type": "paragraph", "raw_content": "

and

", "content": [{"c": "and", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$u_3$$

", "content": {"math_content": "u_3", "math_type": "latex", "by": "mathjax_mock"}}, {"type": "paragraph", "raw_content": "

, which can be verified by the reciprocal property\n of the cubic root of unity from the equation

", "content": [{"c": ", which can be verified by the reciprocal property of the cubic root of unity from the equation", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$v=\\dfrac{20}{9u}$$

", "content": {"math_content": "v=\\dfrac{20}{9u}", "math_type": "latex", "by": "mathjax_mock"}}, {"type": "paragraph", "raw_content": "

. The radicand can be taken as the\n negative conjugate of that in

", "content": [{"c": ". The radicand can be taken as the negative conjugate of that in", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$u_1$$

", "content": {"math_content": "u_1", "math_type": "latex", "by": "mathjax_mock"}}, {"type": "paragraph", "raw_content": "

,

", "content": [{"c": ",", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$u_2$$

", "content": {"math_content": "u_2", "math_type": "latex", "by": "mathjax_mock"}}, {"type": "paragraph", "raw_content": "

and

", "content": [{"c": "and", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$u_3$$

", "content": {"math_content": "u_3", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

, which is the same in value.

", "content": [{"c": ", which is the same in value.", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$\\begin{cases} v_1=\\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ v_2=\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ v_3=\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{cases}$$

", "content": {"math_content": "\\begin{cases} v_1=\\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ v_2=\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ v_3=\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{cases}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Verification for the redicand in

", "content": [{"c": "Verification for the redicand in", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$v$$

", "content": {"math_content": "v", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

.

", "content": [{"c": ".", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$\\begin{aligned} \\\\v_1&=\\dfrac{20}{9u_1}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{1}{\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{1}{\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\Big(\\dfrac{101}{54}\\Big)^2-\\Big(\\dfrac{\\sqrt{521}}{6}\\Big)^2}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\dfrac{10201}{2916}-\\dfrac{521}{36}}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\dfrac{-1\\cdot 20^3}{9^3}}}\\\\ & =-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{aligned}$$

", "content": {"math_content": "\\begin{aligned} \\\\v_1&=\\dfrac{20}{9u_1}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{1}{\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{1}{\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\Big(\\dfrac{101}{54}\\Big)^2-\\Big(\\dfrac{\\sqrt{521}}{6}\\Big)^2}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\dfrac{10201}{2916}-\\dfrac{521}{36}}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\dfrac{-1\\cdot 20^3}{9^3}}}\\\\ & =-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{aligned}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Since

", "content": [{"c": "Since", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$x=u-v$$

", "content": {"math_content": "x=u-v", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

, combining the real and imaginary parts gives\n 3 results for

", "content": [{"c": ", combining the real and imaginary parts gives 3 results for", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$t$$

", "content": {"math_content": "t", "math_type": "latex", "by": "katex"}}, {"type": "equation-interline", "raw_content": "

$$\\begin{aligned} \\\\t_1&=u_1-v_1\\\\ & =\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{aligned}$$

", "content": {"math_content": "\\begin{aligned} \\\\t_1&=u_1-v_1\\\\ & =\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{aligned}", "math_type": "latex", "by": "katex"}}, {"type": "equation-interline", "raw_content": "

$$\\begin{aligned} \\\\t_2&=u_2-v_2\\\\ & =\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\Big(\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}$$

", "content": {"math_content": "\\begin{aligned} \\\\t_2&=u_2-v_2\\\\ & =\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\Big(\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}", "math_type": "latex", "by": "katex"}}, {"type": "equation-interline", "raw_content": "

$$\\begin{aligned} \\\\t_3&=u_3-v_3\\\\ & =\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\Big(\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}$$

", "content": {"math_content": "\\begin{aligned} \\\\t_3&=u_3-v_3\\\\ & =\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\Big(\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}", "math_type": "latex", "by": "katex"}}, {"type": "title", "raw_content": "

3. Vieta's Substitution

", "content": {"title_content": "3. Vieta's Substitution", "level": "2"}}, {"type": "paragraph", "raw_content": "

In Cardano' solution,

", "content": [{"c": "In Cardano' solution,", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$t$$

", "content": {"math_content": "t", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

is defined as the difference of

", "content": [{"c": "is defined as the difference of", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$u$$

", "content": {"math_content": "u", "math_type": "latex", "by": "mathjax_mock"}}, {"type": "paragraph", "raw_content": "

and\n

", "content": [{"c": "and", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$v$$

", "content": {"math_content": "v", "math_type": "latex", "by": "mathjax_mock"}}, {"type": "paragraph", "raw_content": "

. If we substitute the value of

", "content": [{"c": ". If we substitute the value of", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$v$$

", "content": {"math_content": "v", "math_type": "latex", "by": "mathjax_mock"}}, {"type": "paragraph", "raw_content": "

(4) into (2), we get the\n equation.

", "content": [{"c": "(4) into (2), we get the equation.", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$t=u-\\dfrac{20}{9u}$$

", "content": {"math_content": "t=u-\\dfrac{20}{9u}", "math_type": "latex", "by": "mathjax_mock"}}, {"type": "paragraph", "raw_content": "

. And then substitute the equation to the cubic equation\n

", "content": [{"c": ". And then substitute the equation to the cubic equation", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$t^3+\\dfrac{20}{3}t-\\dfrac{101}{27}=0$$

", "content": {"math_content": "t^3+\\dfrac{20}{3}t-\\dfrac{101}{27}=0", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

. This method is called Vieta's Substitution\n for solving a cubic equation, which simplied the Cardano' solution. The substitution\n expression can be obtained by the following formula directly.

", "content": [{"c": ". This method is called Vieta's Substitution for solving a cubic equation, which simplied the Cardano' solution. The substitution expression can be obtained by the following formula directly.", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$t=u-\\dfrac{p}{3u}$$

", "content": {"math_content": "t=u-\\dfrac{p}{3u}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Substitute the expression

", "content": [{"c": "Substitute the expression", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$t=u-\\dfrac{20}{9u}$$

", "content": {"math_content": "t=u-\\dfrac{20}{9u}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

to the cubic equation

", "content": [{"c": "to the cubic equation", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$\\Big(u-\\dfrac{20}{9u}\\Big)^3+\\dfrac{20}{3}\\Big(u-\\dfrac{20}{9u}\\Big)-\\dfrac{101}{27}=0$$

", "content": {"math_content": "\\Big(u-\\dfrac{20}{9u}\\Big)^3+\\dfrac{20}{3}\\Big(u-\\dfrac{20}{9u}\\Big)-\\dfrac{101}{27}=0", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Expand brackets and cancel the like terms

", "content": [{"c": "Expand brackets and cancel the like terms", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$u^3-\\cancel{\\dfrac{20}{3}u^2\\dfrac{1}{u}}+\\cancel{\\dfrac{400}{27}u\\dfrac{1}{u^2}}-\\dfrac{8000}{729}\\dfrac{1}{u^3}+\\cancel{\\dfrac{20}{3}u}-\\cancel{\\dfrac{400}{27}\\dfrac{1}{u}}-\\dfrac{101}{27}=0$$

", "content": {"math_content": "u^3-\\cancel{\\dfrac{20}{3}u^2\\dfrac{1}{u}}+\\cancel{\\dfrac{400}{27}u\\dfrac{1}{u^2}}-\\dfrac{8000}{729}\\dfrac{1}{u^3}+\\cancel{\\dfrac{20}{3}u}-\\cancel{\\dfrac{400}{27}\\dfrac{1}{u}}-\\dfrac{101}{27}=0", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Then we get the same equation as (2)

", "content": [{"c": "Then we get the same equation as (2)", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$u^3-\\dfrac{8000}{729}\\dfrac{1}{u^3}-\\dfrac{101}{27}=0$$

", "content": {"math_content": "u^3-\\dfrac{8000}{729}\\dfrac{1}{u^3}-\\dfrac{101}{27}=0", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

The rest of the steps will be the same as those of Cardano's solution

", "content": [{"c": "The rest of the steps will be the same as those of Cardano's solution", "t": "text"}]}, {"type": "title", "raw_content": "

4. Euler's Solution

", "content": {"title_content": "4. Euler's Solution", "level": "2"}}, {"type": "equation-interline", "raw_content": "

$$t^3+\\dfrac{20}{3}t-\\dfrac{101}{27}=0$$

", "content": {"math_content": "t^3+\\dfrac{20}{3}t-\\dfrac{101}{27}=0", "math_type": "latex", "by": "mathjax_mock"}}, {"type": "paragraph", "raw_content": "

Move the linear term and constant of (1) to its right hand side.\n We get the following form of the equation.

", "content": [{"c": "Move the linear term and constant of (1) to its right hand side. We get the following form of the equation.", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$t^3=-\\dfrac{20}{3}t+\\dfrac{101}{27} $$

", "content": {"math_content": "t^3=-\\dfrac{20}{3}t+\\dfrac{101}{27}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

3

", "content": [{"c": "3", "t": "text"}]}, {"type": "paragraph", "raw_content": "

Let the root of the cubic equation be the sum of two cubic roots

", "content": [{"c": "Let the root of the cubic equation be the sum of two cubic roots", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$t=\\sqrt[3]{r_1}+\\sqrt[3]{r_2} $$

", "content": {"math_content": "t=\\sqrt[3]{r_1}+\\sqrt[3]{r_2}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

4

", "content": [{"c": "4", "t": "text"}]}, {"type": "paragraph", "raw_content": "

in which

", "content": [{"c": "in which", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$r_1$$

", "content": {"math_content": "r_1", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

and

", "content": [{"c": "and", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$r_2$$

", "content": {"math_content": "r_2", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

are two roots of a quadratic equation

", "content": [{"c": "are two roots of a quadratic equation", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$z^2-\\alpha z+ β=0 $$

", "content": {"math_content": "z^2-\\alpha z+ β=0", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

5

", "content": [{"c": "5", "t": "text"}]}, {"type": "paragraph", "raw_content": "

Using Vieta's Formula, the following equations are established.

", "content": [{"c": "Using Vieta's Formula, the following equations are established.", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$r_1+r_2 = \\alpha \\quad \\text{and} \\quad r_1r_2 = β $$

", "content": {"math_content": "r_1+r_2 = \\alpha \\quad \\text{and} \\quad r_1r_2 = β", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

To determine

", "content": [{"c": "To determine", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$\\alpha$$

", "content": {"math_content": "\\alpha", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

,

", "content": [{"c": ",", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$β$$

", "content": {"math_content": "β", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

, cube both sides of the equation (4)

", "content": [{"c": ", cube both sides of the equation (4)", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$t^3=3\\sqrt[3]{r_1r_2}(\\sqrt[3]{r_1}+\\sqrt[3]{r_2})+r_1+r_2 $$

", "content": {"math_content": "t^3=3\\sqrt[3]{r_1r_2}(\\sqrt[3]{r_1}+\\sqrt[3]{r_2})+r_1+r_2", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Substituting, the equation is simplified to

", "content": [{"c": "Substituting, the equation is simplified to", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$t^3=3\\sqrt[3]{β}t+\\alpha $$

", "content": {"math_content": "t^3=3\\sqrt[3]{β}t+\\alpha", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Compare the cubic equation with (3), the following equations are established

", "content": [{"c": "Compare the cubic equation with (3), the following equations are established", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$\\begin{cases} 3\\sqrt[3]{β}=-\\dfrac{20}{3}\\\\ \\alpha=\\dfrac{101}{27}\\\\ \\end{cases}$$

", "content": {"math_content": "\\begin{cases} 3\\sqrt[3]{β}=-\\dfrac{20}{3}\\\\ \\alpha=\\dfrac{101}{27}\\\\ \\end{cases}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Solving for

", "content": [{"c": "Solving for", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$β$$

", "content": {"math_content": "β", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

gives

", "content": [{"c": "gives", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$β=-\\dfrac{8000}{729} $$

", "content": {"math_content": "β=-\\dfrac{8000}{729}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

So the quadratic equation (5) is determined as

", "content": [{"c": "So the quadratic equation (5) is determined as", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$z^2-\\dfrac{101}{27}z-\\dfrac{8000}{729}=0$$

", "content": {"math_content": "z^2-\\dfrac{101}{27}z-\\dfrac{8000}{729}=0", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

6

", "content": [{"c": "6", "t": "text"}]}, {"type": "paragraph", "raw_content": "

Solving the quadratic equation yields

", "content": [{"c": "Solving the quadratic equation yields", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$\\begin{cases} r_1=\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\approx5.6746077738748\\\\ r_2=\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}\\approx-1.9338670331341\\\\ \\end{cases}$$

", "content": {"math_content": "\\begin{cases} r_1=\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\approx5.6746077738748\\\\ r_2=\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}\\approx-1.9338670331341\\\\ \\end{cases}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Therefore, one of the roots of the cubic equation could be obtained from (4).

", "content": [{"c": "Therefore, one of the roots of the cubic equation could be obtained from (4).", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$t_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}} $$

", "content": {"math_content": "t_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

in decimals,

", "content": [{"c": "in decimals,", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$t_1=0.53778143658824 $$

", "content": {"math_content": "t_1=0.53778143658824", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

However, since the cube root of a quantity has triple values,

", "content": [{"c": "However, since the cube root of a quantity has triple values,", "t": "text"}]}, {"type": "paragraph", "raw_content": "

The other two roots could be determined as,

", "content": [{"c": "The other two roots could be determined as,", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$t_2=\\dfrac{-1+i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\dfrac{-1-i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}} $$

", "content": {"math_content": "t_2=\\dfrac{-1+i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\dfrac{-1-i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}", "math_type": "latex", "by": "katex"}}, {"type": "equation-interline", "raw_content": "

$$t_3=\\dfrac{-1-i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\dfrac{-1+i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}} $$

", "content": {"math_content": "t_3=\\dfrac{-1-i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\dfrac{-1+i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Combining the real and imaginary parts\n results in the same result as that obtained by Cardano's solution.

", "content": [{"c": "Combining the real and imaginary parts results in the same result as that obtained by Cardano's solution.", "t": "text"}]}, {"type": "paragraph", "raw_content": "

For the equation

", "content": [{"c": "For the equation", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$t^3 +\\dfrac{20}{3}t-\\dfrac{101}{27}$$

", "content": {"math_content": "t^3 +\\dfrac{20}{3}t-\\dfrac{101}{27}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

, we have

", "content": [{"c": ", we have", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$p=\\dfrac{20}{3}$$

", "content": {"math_content": "p=\\dfrac{20}{3}", "math_type": "latex", "by": "mathjax_mock"}}, {"type": "paragraph", "raw_content": "

and

", "content": [{"c": "and", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$q = -\\dfrac{101}{27}$$

", "content": {"math_content": "q = -\\dfrac{101}{27}", "math_type": "latex", "by": "katex"}}, {"type": "title", "raw_content": "

Calculate the discriminant

", "content": {"title_content": "Calculate the discriminant", "level": "3"}}, {"type": "paragraph", "raw_content": "

The nature of the roots are determined by the sign of the discriminant.

", "content": [{"c": "The nature of the roots are determined by the sign of the discriminant.", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$\\begin{aligned} \\\\\\Delta&=\\dfrac{q^2}{4}+\\dfrac{p^3}{27}\\\\ & =\\dfrac{\\Big(-\\dfrac{101}{27}\\Big)^2}{4}+\\dfrac{\\Big(\\dfrac{20}{3}\\Big)^3}{27}\\\\ & =\\dfrac{10201}{2916}+\\dfrac{8000}{729}\\\\ & =\\dfrac{10201\\cdot 1+8000\\cdot 4}{2916}\\\\ & =14.472222222222\\\\ \\end{aligned}$$

", "content": {"math_content": "\\begin{aligned} \\\\\\Delta&=\\dfrac{q^2}{4}+\\dfrac{p^3}{27}\\\\ & =\\dfrac{\\Big(-\\dfrac{101}{27}\\Big)^2}{4}+\\dfrac{\\Big(\\dfrac{20}{3}\\Big)^3}{27}\\\\ & =\\dfrac{10201}{2916}+\\dfrac{8000}{729}\\\\ & =\\dfrac{10201\\cdot 1+8000\\cdot 4}{2916}\\\\ & =14.472222222222\\\\ \\end{aligned}", "math_type": "latex", "by": "katex"}}, {"type": "title", "raw_content": "

4.1 Use the root formula directly

", "content": {"title_content": "4.1 Use the root formula directly", "level": "3"}}, {"type": "paragraph", "raw_content": "

If the discriminant is greater than zero, we can use the root formula to determine the roots of the cubic equation.

", "content": [{"c": "If the discriminant is greater than zero, we can use the root formula to determine the roots of the cubic equation.", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$t_{1,2,3} =\\begin{cases} \\sqrt[3]{-\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} } } +\\sqrt[3]{-\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }}& \\\\ ω\\cdotp \\sqrt[3]{-\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} } } + \\overline{ω} \\sqrt[3]{-\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }}&\\ \\\\ \\overline{ω}\\cdotp \\sqrt[3]{-\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} } } + ω\\cdotp \\sqrt[3]{-\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }} \\end{cases}$$

", "content": {"math_content": "t_{1,2,3} =\\begin{cases} \\sqrt[3]{-\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} } } +\\sqrt[3]{-\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }}& \\\\ ω\\cdotp \\sqrt[3]{-\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} } } + \\overline{ω} \\sqrt[3]{-\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }}&\\ \\\\ \\overline{ω}\\cdotp \\sqrt[3]{-\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} } } + ω\\cdotp \\sqrt[3]{-\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }} \\end{cases}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

in which,

", "content": [{"c": "in which,", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$ ω = \\dfrac{-1+i\\sqrt{3}}{2} $$

", "content": {"math_content": "ω = \\dfrac{-1+i\\sqrt{3}}{2}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

and

", "content": [{"c": "and", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$ \\overline{ω} =\\dfrac{-1-i\\sqrt{3}}{2}$$

", "content": {"math_content": "\\overline{ω} =\\dfrac{-1-i\\sqrt{3}}{2}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

Substitute the values of

", "content": [{"c": "Substitute the values of", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$p, q$$

", "content": {"math_content": "p, q", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

and

", "content": [{"c": "and", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$\\Delta$$

", "content": {"math_content": "\\Delta", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

which we have calculated. Then,

", "content": [{"c": "which we have calculated. Then,", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$\\begin{aligned} \\\\t_1&=\\sqrt[3]{\\dfrac{101}{54}+\\sqrt{\\dfrac{42201}{2916}}}+\\sqrt[3]{\\dfrac{101}{54}-\\sqrt{\\dfrac{42201}{2916}}}\\\\ & =\\sqrt[3]{\\dfrac{101}{54}+\\sqrt{\\dfrac{521\\cdot\\cancel{81}}{36\\cdot\\cancel{81}}}}+\\sqrt[3]{\\dfrac{101}{54}-\\sqrt{\\dfrac{521\\cdot\\cancel{81}}{36\\cdot\\cancel{81}}}}\\\\ & =\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{aligned}$$

", "content": {"math_content": "\\begin{aligned} \\\\t_1&=\\sqrt[3]{\\dfrac{101}{54}+\\sqrt{\\dfrac{42201}{2916}}}+\\sqrt[3]{\\dfrac{101}{54}-\\sqrt{\\dfrac{42201}{2916}}}\\\\ & =\\sqrt[3]{\\dfrac{101}{54}+\\sqrt{\\dfrac{521\\cdot\\cancel{81}}{36\\cdot\\cancel{81}}}}+\\sqrt[3]{\\dfrac{101}{54}-\\sqrt{\\dfrac{521\\cdot\\cancel{81}}{36\\cdot\\cancel{81}}}}\\\\ & =\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{aligned}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

If we denote

", "content": [{"c": "If we denote", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$R = -\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }$$

", "content": {"math_content": "R = -\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }", "math_type": "latex", "by": "katex"}}, {"type": "equation-interline", "raw_content": "

$$\\overline{R} = -\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }$$

", "content": {"math_content": "\\overline{R} = -\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

then,

", "content": [{"c": "then,", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$\\sqrt[3]{R} = \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}$$

", "content": {"math_content": "\\sqrt[3]{R} = \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

,

", "content": [{"c": ",", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$\\sqrt[3]{\\overline{R}} =\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}$$

", "content": {"math_content": "\\sqrt[3]{\\overline{R}} =\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}", "math_type": "latex", "by": "katex"}}, {"type": "equation-interline", "raw_content": "

$$\\begin{aligned} \\\\t_2&= ω\\cdotp \\sqrt[3]{R}+ \\overline{ω} \\sqrt[3]{\\overline{R} }\\\\ & =\\dfrac{-\\sqrt[3]{R}-\\sqrt[3]{\\overline{R} }}{2} +\\dfrac{\\sqrt{3}( \\sqrt[3]{R} - \\sqrt[3]{\\overline{R} }) }{2} i\\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\&+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}$$

", "content": {"math_content": "\\begin{aligned} \\\\t_2&= ω\\cdotp \\sqrt[3]{R}+ \\overline{ω} \\sqrt[3]{\\overline{R} }\\\\ & =\\dfrac{-\\sqrt[3]{R}-\\sqrt[3]{\\overline{R} }}{2} +\\dfrac{\\sqrt{3}( \\sqrt[3]{R} - \\sqrt[3]{\\overline{R} }) }{2} i\\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\&+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}", "math_type": "latex", "by": "katex"}}, {"type": "equation-interline", "raw_content": "

$$\\begin{aligned} \\\\t_3&= \\overline{ω}\\cdotp \\sqrt[3]{R}+ ω\\cdotp \\sqrt[3]{\\overline{R}}\\\\ & =\\dfrac{-\\sqrt[3]{R}-\\sqrt[3]{\\overline{R} }}{2} +\\dfrac{\\sqrt{3}(- \\sqrt[3]{R} + \\sqrt[3]{\\overline{R} }) }{2}i \\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\&-\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}$$

", "content": {"math_content": "\\begin{aligned} \\\\t_3&= \\overline{ω}\\cdotp \\sqrt[3]{R}+ ω\\cdotp \\sqrt[3]{\\overline{R}}\\\\ & =\\dfrac{-\\sqrt[3]{R}-\\sqrt[3]{\\overline{R} }}{2} +\\dfrac{\\sqrt{3}(- \\sqrt[3]{R} + \\sqrt[3]{\\overline{R} }) }{2}i \\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\&-\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}", "math_type": "latex", "by": "katex"}}, {"type": "title", "raw_content": "

Roots of the general cubic equation

", "content": {"title_content": "Roots of the general cubic equation", "level": "2"}}, {"type": "paragraph", "raw_content": "

Since

", "content": [{"c": "Since", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$x = t - \\dfrac{b}{3a}$$

", "content": {"math_content": "x = t - \\dfrac{b}{3a}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

, substituting the values of

", "content": [{"c": ", substituting the values of", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$t$$

", "content": {"math_content": "t", "math_type": "latex", "by": "mathjax_mock"}}, {"type": "paragraph", "raw_content": "

,

", "content": [{"c": ",", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$a$$

", "content": {"math_content": "a", "math_type": "latex", "by": "mathjax_mock"}}, {"type": "paragraph", "raw_content": "

and

", "content": [{"c": "and", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$b$$

", "content": {"math_content": "b", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

gives

", "content": [{"c": "gives", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$x_1 = t_1-\\dfrac{2}{3}$$

", "content": {"math_content": "x_1 = t_1-\\dfrac{2}{3}", "math_type": "latex", "by": "katex"}}, {"type": "equation-interline", "raw_content": "

$$x_2 = t_2-\\dfrac{2}{3}$$

", "content": {"math_content": "x_2 = t_2-\\dfrac{2}{3}", "math_type": "latex", "by": "katex"}}, {"type": "equation-interline", "raw_content": "

$$x_3 = t_3-\\dfrac{2}{3}$$

", "content": {"math_content": "x_3 = t_3-\\dfrac{2}{3}", "math_type": "latex", "by": "katex"}}, {"type": "title", "raw_content": "

5. Summary

", "content": {"title_content": "5. Summary", "level": "2"}}, {"type": "paragraph", "raw_content": "

In summary, we have tried the method of cubic root formula to explore the solutions of the equation. The cubic equation

", "content": [{"c": "In summary, we have tried the method of cubic root formula to explore the solutions of the equation. The cubic equation", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$x³ + 2x² + 8x + 1=0$$

", "content": {"math_content": "x³ + 2x² + 8x + 1=0", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

is found to have one real root and two complex roots. Exact values and approximations are given below.

", "content": [{"c": "is found to have one real root and two complex roots. Exact values and approximations are given below.", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$\\begin{cases} x_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}-\\dfrac{2}{3} \\\\ x_2=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\\\ x_3=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)-\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\end{cases}$$

", "content": {"math_content": "\\begin{cases} x_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}-\\dfrac{2}{3} \\\\ x_2=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\\\ x_3=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)-\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\end{cases}", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

in decimal notation,

", "content": [{"c": "in decimal notation,", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$\\begin{cases} x_1=-0.12888523007843 \\\\ x_2=-0.93555738496079+2.6236564793854i \\\\ x_3=-0.93555738496079-2.6236564793854i \\end{cases}$$

", "content": {"math_content": "\\begin{cases} x_1=-0.12888523007843 \\\\ x_2=-0.93555738496079+2.6236564793854i \\\\ x_3=-0.93555738496079-2.6236564793854i \\end{cases}", "math_type": "latex", "by": "katex"}}, {"type": "title", "raw_content": "

6. Graph for the function

", "content": {"title_content": "6. Graph for the function", "level": "2"}}, {"type": "equation-interline", "raw_content": "

$$f(x) = x³ + 2x² + 8x + 1$$

", "content": {"math_content": "f(x) = x³ + 2x² + 8x + 1", "math_type": "latex", "by": "mathjax_mock"}}, {"type": "paragraph", "raw_content": "

Since the discriminat is greater than zero, the curve of the cubic function

", "content": [{"c": "Since the discriminat is greater than zero, the curve of the cubic function", "t": "text"}]}, {"type": "equation-interline", "raw_content": "

$$f(x) = x³ + 2x² + 8x + 1$$

", "content": {"math_content": "f(x) = x³ + 2x² + 8x + 1", "math_type": "latex", "by": "katex"}}, {"type": "paragraph", "raw_content": "

has one intersection point with the x-axis.

", "content": [{"c": "has one intersection point with the x-axis.", "t": "text"}]}, {"type": "title", "raw_content": "

More cubic equations

", "content": {"title_content": "More cubic equations", "level": "2"}}]], "html": "\n\n\n\n\n\nSolve x^3+2x^2+8x+1=0 | Uniteasy.com\n\n\n\n\n\n\n\n\n\n\n\n \n
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\n

Solve the cubic equation:

\n

$$x^3+2x^2+8x+1=0 $$

\n

Quick Answer

\n

Since the discriminant $$\\Delta >0$$, the cubic equation has one real root and two conjugate complex roots.

$$ \\Delta=14.472222222222$$

$$\\begin{cases} x_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}-\\dfrac{2}{3} \\\\ x_2=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\\\ x_3=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)-\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\end{cases}$$

In decimals,

$$\\begin{cases} x_1=-0.12888523007843 \\\\ x_2=-0.93555738496079+2.6236564793854i \\\\ x_3=-0.93555738496079-2.6236564793854i \\end{cases}$$

Detailed Steps on Solution

1. Convert to depressed cubic equation

The idea is to convert general form of cubic equation

$$ax^3+bx^2+cx+d = 0$$

to the form without quadratic term.

$$t^3+pt+q = 0$$

By substituting $$x$$ with $$t - \\dfrac{b}{3a}$$, the general cubic equation could be transformed to

$$t^3+\\dfrac{3ac-b^2}{3a^2}t+\\dfrac{2b^3-9abc+27a^2d}{27a^3} = 0 $$

Compare with the depressed cubic equation. Then,

$$p = \\dfrac{3ac-b^2}{3a^2}$$

$$q = \\dfrac{2b^3-9abc+27a^2d}{27a^3} $$

Substitute the values of coefficients, $$p, q$$ is obtained as

$$p = \\dfrac{3\\cdot 1\\cdot 8-2^2}{3\\cdot 1^2}=\\dfrac{20}{3}$$

$$q = \\dfrac{2\\cdot 2^3-9\\cdot1\\cdot 2\\cdot 8+27\\cdot 1^2\\cdot1}{27\\cdot 1^3}=-\\dfrac{101}{27}$$

Use the substitution to transform

Let $$p$$ and $$q$$ being the coefficient of the linean and constant terms, the depressed cubic equation is expressed as.

$$t^3 +pt+q=0$$

Let $$x=t-\\dfrac{2}{3}$$

The cubic equation $$x³ + 2x² + 8x + 1=0$$ is transformed to

$$t^3 +\\dfrac{20}{3}t-\\dfrac{101}{27}=0$$

2. Cardano's solution

Let $$t=u-v$$

Cube both sides and extract common factor from two middle terms after expanding the bracket.

$$\\begin{aligned} \\\\t^3&=(u-v)^3\\\\ & =u^3-3u^2v+3uv^2-v^3\\\\ & =-3uv(u-v)+u^3-v^3\\\\ \\end{aligned}$$

Since $$u-v=t$$, substitution gives a linear term for the equation.\n Rearrange terms.

$$x^3+3uvx-u^3+v^3=0$$

Compare the cubic equation with the original one (1)

$$\\begin{cases} 3uv=\\dfrac{20}{3}\\quad\\text{or}\\quad v=\\dfrac{20}{9u}\\\\ v^3-u^3=-\\dfrac{101}{27}\\\\ \\end{cases}$$

$$v=\\dfrac{20}{9u}$$ gives relationship between the two variables. Substitute the value of $$v$$ to the second equation

$$\\Big(\\dfrac{20}{9u}\\Big)^3-u^3=-\\dfrac{101}{27}$$

Simplifying gives,

$$u^3-\\dfrac{8000}{729}\\dfrac{1}{u^3}-\\dfrac{101}{27}=0$$2

Let $$m=u^3$$, then the equation is transformed to a quadratic equation in terms of $$m$$.\n Once the value of $$m$$ is determined, $$v^3$$ could be determined by $$v^3=-\\dfrac{101}{27}+u^3$$.

$$m^2-\\dfrac{101}{27}m-\\dfrac{8000}{729}=0$$

Sovling the quadratic euqation will give two roots (some may be equal). Here we only cosider\n one case with positive sign before the square root radical since the negative case will produce the same result.

$$\\begin{aligned} \\\\u^3=m&=\\dfrac{101}{54}+\\dfrac{1}{2}\\sqrt{\\Big(-\\dfrac{101}{27}^2\\Big)-4\\cdot \\Big(-\\dfrac{8000}{729}\\Big)}\\\\ & =\\dfrac{101}{54}+\\dfrac{1}{2}\\sqrt{\\dfrac{10201}{729}+\\dfrac{32000}{729}}\\\\ & =\\dfrac{101}{54}+\\dfrac{1}{2}\\sqrt{\\dfrac{521}{9}}\\\\ & =\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\\\ \\end{aligned}$$

$$v^3$$ can be determined by the equation we deduced $$v^3-u^3=-\\dfrac{101}{27}$$. Then,

$$\\begin{aligned} \\\\v^3&=-\\dfrac{101}{27}+u^3\\\\ & =-\\dfrac{101}{27}+\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\\\ & =-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\\\ \\end{aligned}$$

Now we have,

$$u^3=\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}$$ and $$v^3=-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}$$

Evaluating the simplest cubic equation $$x^3-A=0$$,\n it has 3 roots, in which the first root is a real number . The second and third are\n expressed in the product of cubic root of unity and the first one.

If $$ω = \\dfrac{-1+i\\sqrt{3}}{2}$$, then its reciprocal is equal to its conjugate, $$\\dfrac{1}{ω}=\\overline{ω}$$.

$$\\begin{cases} r_1=\\sqrt[3]{A}\\\\ r_2=\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{A}\\\\ r_3=\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{A}\\\\ \\end{cases}$$

Similary, taking cubic root for $$u^3$$ and $$v^3$$ also gives 3 roots.

$$\\begin{cases} u_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ u_2=\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ u_3=\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{cases}$$

For $$v_2$$ and $$v_3$$, the complex numbers before radicals are the conjugates of\n those for $$u_2$$ and $$u_3$$, which can be verified by the reciprocal property\n of the cubic root of unity from the equation $$v=\\dfrac{20}{9u}$$. The radicand can be taken as the\n negative conjugate of that in $$u_1$$, $$u_2$$ and $$u_3$$, which is the same in value.

$$\\begin{cases} v_1=\\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ v_2=\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ v_3=\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{cases}$$

Verification for the redicand in $$v$$.

$$\\begin{aligned} \\\\v_1&=\\dfrac{20}{9u_1}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{1}{\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{1}{\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\Big(\\dfrac{101}{54}\\Big)^2-\\Big(\\dfrac{\\sqrt{521}}{6}\\Big)^2}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\dfrac{10201}{2916}-\\dfrac{521}{36}}}\\\\ & =\\dfrac{20}{9}\\cdot \\dfrac{\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}}{\\sqrt[3]{\\dfrac{-1\\cdot 20^3}{9^3}}}\\\\ & =-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{aligned}$$

Since $$x=u-v$$, combining the real and imaginary parts gives\n 3 results for $$t$$

$$\\begin{aligned} \\\\t_1&=u_1-v_1\\\\ & =\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{aligned}$$

$$\\begin{aligned} \\\\t_2&=u_2-v_2\\\\ & =\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\Big(\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}$$

$$\\begin{aligned} \\\\t_3&=u_3-v_3\\\\ & =\\dfrac{-1-i\\sqrt{3}}{2}\\cdot \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\Big(\\dfrac{-1+i\\sqrt{3}}{2}\\cdot \\sqrt[3]{-\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}$$

3. Vieta's Substitution

In Cardano' solution, $$t$$ is defined as the difference of $$u$$ and\n $$v$$. If we substitute the value of $$v$$ (4) into (2), we get the\n equation. $$t=u-\\dfrac{20}{9u}$$. And then substitute the equation to the cubic equation\n $$t^3+\\dfrac{20}{3}t-\\dfrac{101}{27}=0$$. This method is called Vieta's Substitution\n for solving a cubic equation, which simplied the Cardano' solution. The substitution\n expression can be obtained by the following formula directly.

$$t=u-\\dfrac{p}{3u}$$

Substitute the expression $$t=u-\\dfrac{20}{9u}$$ to the cubic equation

$$\\Big(u-\\dfrac{20}{9u}\\Big)^3+\\dfrac{20}{3}\\Big(u-\\dfrac{20}{9u}\\Big)-\\dfrac{101}{27}=0$$

Expand brackets and cancel the like terms

$$u^3-\\cancel{\\dfrac{20}{3}u^2\\dfrac{1}{u}}+\\cancel{\\dfrac{400}{27}u\\dfrac{1}{u^2}}-\\dfrac{8000}{729}\\dfrac{1}{u^3}+\\cancel{\\dfrac{20}{3}u}-\\cancel{\\dfrac{400}{27}\\dfrac{1}{u}}-\\dfrac{101}{27}=0$$

Then we get the same equation as (2)

$$u^3-\\dfrac{8000}{729}\\dfrac{1}{u^3}-\\dfrac{101}{27}=0$$

The rest of the steps will be the same as those of Cardano's solution

4. Euler's Solution

$$t^3+\\dfrac{20}{3}t-\\dfrac{101}{27}=0$$

Move the linear term and constant of (1) to its right hand side.\n We get the following form of the equation.

$$t^3=-\\dfrac{20}{3}t+\\dfrac{101}{27} $$3

Let the root of the cubic equation be the sum of two cubic roots

$$t=\\sqrt[3]{r_1}+\\sqrt[3]{r_2} $$4

in which $$r_1$$ and $$r_2$$ are two roots of a quadratic equation

$$z^2-\\alpha z+ β=0 $$5

Using Vieta's Formula, the following equations are established.

$$r_1+r_2 = \\alpha \\quad \\text{and} \\quad r_1r_2 = β $$

To determine $$\\alpha$$, $$β$$, cube both sides of the equation (4)

$$t^3=3\\sqrt[3]{r_1r_2}(\\sqrt[3]{r_1}+\\sqrt[3]{r_2})+r_1+r_2 $$

Substituting, the equation is simplified to

$$t^3=3\\sqrt[3]{β}t+\\alpha $$

Compare the cubic equation with (3), the following equations are established

$$\\begin{cases} 3\\sqrt[3]{β}=-\\dfrac{20}{3}\\\\ \\alpha=\\dfrac{101}{27}\\\\ \\end{cases}$$

Solving for $$β$$ gives

$$β=-\\dfrac{8000}{729} $$

So the quadratic equation (5) is determined as

$$z^2-\\dfrac{101}{27}z-\\dfrac{8000}{729}=0$$6

Solving the quadratic equation yields

$$\\begin{cases} r_1=\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}\\approx5.6746077738748\\\\ r_2=\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}\\approx-1.9338670331341\\\\ \\end{cases}$$

Therefore, one of the roots of the cubic equation could be obtained from (4).

$$t_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}} $$

in decimals,

$$t_1=0.53778143658824 $$

However, since the cube root of a quantity has triple values,

The other two roots could be determined as,

$$t_2=\\dfrac{-1+i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\dfrac{-1-i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}} $$

$$t_3=\\dfrac{-1-i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\dfrac{-1+i\\sqrt{3}}{2}\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}} $$

Combining the real and imaginary parts\n results in the same result as that obtained by Cardano's solution.

For the equation $$t^3 +\\dfrac{20}{3}t-\\dfrac{101}{27}$$, we have $$p=\\dfrac{20}{3}$$ and $$q = -\\dfrac{101}{27}$$

Calculate the discriminant

The nature of the roots are determined by the sign of the discriminant.

$$\\begin{aligned} \\\\\\Delta&=\\dfrac{q^2}{4}+\\dfrac{p^3}{27}\\\\ & =\\dfrac{\\Big(-\\dfrac{101}{27}\\Big)^2}{4}+\\dfrac{\\Big(\\dfrac{20}{3}\\Big)^3}{27}\\\\ & =\\dfrac{10201}{2916}+\\dfrac{8000}{729}\\\\ & =\\dfrac{10201\\cdot 1+8000\\cdot 4}{2916}\\\\ & =14.472222222222\\\\ \\end{aligned}$$

4.1 Use the root formula directly

If the discriminant is greater than zero, we can use the root formula to determine the roots of the cubic equation.

$$t_{1,2,3} =\\begin{cases} \\sqrt[3]{-\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} } } +\\sqrt[3]{-\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }}& \\\\ ω\\cdotp \\sqrt[3]{-\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} } } + \\overline{ω} \\sqrt[3]{-\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }}&\\ \\\\ \\overline{ω}\\cdotp \\sqrt[3]{-\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} } } + ω\\cdotp \\sqrt[3]{-\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }} \\end{cases}$$

in which, $$ ω = \\dfrac{-1+i\\sqrt{3}}{2} $$ and $$ \\overline{ω} =\\dfrac{-1-i\\sqrt{3}}{2}$$

Substitute the values of $$p, q$$ and $$\\Delta$$ which we have calculated. Then,

$$\\begin{aligned} \\\\t_1&=\\sqrt[3]{\\dfrac{101}{54}+\\sqrt{\\dfrac{42201}{2916}}}+\\sqrt[3]{\\dfrac{101}{54}-\\sqrt{\\dfrac{42201}{2916}}}\\\\ & =\\sqrt[3]{\\dfrac{101}{54}+\\sqrt{\\dfrac{521\\cdot\\cancel{81}}{36\\cdot\\cancel{81}}}}+\\sqrt[3]{\\dfrac{101}{54}-\\sqrt{\\dfrac{521\\cdot\\cancel{81}}{36\\cdot\\cancel{81}}}}\\\\ & =\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\\\ \\end{aligned}$$

If we denote

$$R = -\\dfrac{q}{2}+\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }$$

$$\\overline{R} = -\\dfrac{q}{2} -\\sqrt{\\dfrac{q^2}{4}+\\dfrac{p^3}{27} }$$

then,

$$\\sqrt[3]{R} = \\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}$$, $$\\sqrt[3]{\\overline{R}} =\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}$$

$$\\begin{aligned} \\\\t_2&= ω\\cdotp \\sqrt[3]{R}+ \\overline{ω} \\sqrt[3]{\\overline{R} }\\\\ & =\\dfrac{-\\sqrt[3]{R}-\\sqrt[3]{\\overline{R} }}{2} +\\dfrac{\\sqrt{3}( \\sqrt[3]{R} - \\sqrt[3]{\\overline{R} }) }{2} i\\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\&+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}$$

$$\\begin{aligned} \\\\t_3&= \\overline{ω}\\cdotp \\sqrt[3]{R}+ ω\\cdotp \\sqrt[3]{\\overline{R}}\\\\ & =\\dfrac{-\\sqrt[3]{R}-\\sqrt[3]{\\overline{R} }}{2} +\\dfrac{\\sqrt{3}(- \\sqrt[3]{R} + \\sqrt[3]{\\overline{R} }) }{2}i \\\\ & =\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)\\\\&-\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i\\\\ \\end{aligned}$$

Roots of the general cubic equation

Since $$x = t - \\dfrac{b}{3a}$$, substituting the values of $$t$$, $$a$$ and $$b$$ gives

$$x_1 = t_1-\\dfrac{2}{3}$$

$$x_2 = t_2-\\dfrac{2}{3}$$

$$x_3 = t_3-\\dfrac{2}{3}$$

5. Summary

In summary, we have tried the method of cubic root formula to explore the solutions of the equation. The cubic equation $$x³ + 2x² + 8x + 1=0$$ is found to have one real root and two complex roots. Exact values and approximations are given below.

$$\\begin{cases} x_1=\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}+\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}-\\dfrac{2}{3} \\\\ x_2=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)+\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\\\ x_3=\\dfrac{1}{2}\\Big(-\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)-\\dfrac{\\sqrt{3}}{2}\\Big(\\sqrt[3]{\\dfrac{101}{54}+\\dfrac{\\sqrt{521}}{6}}-\\sqrt[3]{\\dfrac{101}{54}-\\dfrac{\\sqrt{521}}{6}}\\Big)i-\\dfrac{2}{3} \\end{cases}$$

in decimal notation,

$$\\begin{cases} x_1=-0.12888523007843 \\\\ x_2=-0.93555738496079+2.6236564793854i \\\\ x_3=-0.93555738496079-2.6236564793854i \\end{cases}$$

6. Graph for the function $$f(x) = x³ + 2x² + 8x + 1$$

Since the discriminat is greater than zero, the curve of the cubic function $$f(x) = x³ + 2x² + 8x + 1$$ has one intersection point with the x-axis.

\n\n\n\n\n\n\n
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More cubic equations

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\nScroll to Top\n
\n\n
\n\n\n", "statics": {"title": 12, "equation-interline": 124, "paragraph": 119, "paragraph.text": 119}} diff --git a/bench/data/groundtruth/math_katex_latex_3.jsonl b/bench/data/groundtruth/math_katex_latex_3.jsonl index ac465409..132af8f9 100644 --- a/bench/data/groundtruth/math_katex_latex_3.jsonl +++ b/bench/data/groundtruth/math_katex_latex_3.jsonl @@ -1 +1 @@ -{"content_list": [[{"type": "paragraph", "raw_content": "
\n Show commands:\n Magma\n / PariGP\n / SageMath
", "content": [{"c": "Show commands: Magma/ PariGP/ SageMath", "t": "text"}]}, {"type": "paragraph", "raw_content": "
[N,k,chi] = [3332,1,Mod(667,3332)]
mf = mfinit([N,k,chi],0)
lf = mfeigenbasis(mf)
", "content": [{"c": "[N,k,chi] = [3332,1,Mod(667,3332)] mf = mfinit([N,k,chi],0) lf = mfeigenbasis(mf)", "t": "text"}]}, {"type": "paragraph", "raw_content": "
from sage.modular.dirichlet import DirichletCharacter
H = DirichletGroup(3332, base_ring=CyclotomicField(12))
chi = DirichletCharacter(H, H._module([6, 4, 9]))
N = Newforms(chi, 1, names=\"a\")
", "content": [{"c": "from sage.modular.dirichlet import DirichletCharacter H = DirichletGroup(3332, base_ring=CyclotomicField(12)) chi = DirichletCharacter(H, H._module([6, 4, 9])) N = Newforms(chi, 1, names=\"a\")", "t": "text"}]}, {"type": "paragraph", "raw_content": "
//Please install CHIMP (https://github.com/edgarcosta/CHIMP) if you want to run this code
chi := DirichletCharacter(\"3332.667\");
S:= CuspForms(chi, 1);
N := Newforms(S);
", "content": [{"c": "//Please install CHIMP (https://github.com/edgarcosta/CHIMP) if you want to run this code chi := DirichletCharacter(\"3332.667\"); S:= CuspForms(chi, 1); N := Newforms(S);", "t": "text"}]}, {"type": "table", "raw_content": "
Level: \\( N \\) \\(=\\)\\( 3332 = 2^{2} \\cdot 7^{2} \\cdot 17 \\)
Weight: \\( k \\) \\(=\\)\\( 1 \\)
Character orbit: \\([\\chi]\\) \\(=\\)3332.bc (of order \\(12\\), degree \\(4\\), not minimal)
", "content": {"html": "
Level\\( N \\)\\(=\\)\\( 3332 = 2^{2} \\cdot 7^{2} \\cdot 17 \\)
Weight\\( k \\)\\(=\\)\\( 1 \\)
Character orbit\\([\\chi]\\)\\(=\\)3332.bc<br>order<br>degree<br>minimal
", "is_complex": false, "table_nest_level": "1"}}, {"type": "title", "raw_content": "

Newform invariants

", "content": {"title_content": "Newform invariants", "level": "2"}}, {"type": "paragraph", "raw_content": "
sage:\u00a0f = N[0] # Warning: the index may be different
", "content": [{"c": "sage:\u00a0f = N[0] # Warning: the index may be different", "t": "text"}]}, {"type": "paragraph", "raw_content": "
gp:\u00a0f = lf[1] \\\\ Warning: the index may be different
", "content": [{"c": "gp:\u00a0f = lf[1] \\\\ Warning: the index may be different", "t": "text"}]}, {"type": "table", "raw_content": "
Self dual: no
Analytic conductor: \\(1.66288462209\\)
Analytic rank: \\(0\\)
Dimension: \\(4\\)
Coefficient field: \\(\\Q(\\zeta_{12})\\)
gp:\u00a0f.mod \\\\ as an extension of the character field
Defining polynomial: \\( x^{4} - x^{2} + 1 \\)\"Copy\"Toggle
Coefficient ring: \\(\\Z[a_1, a_2]\\)
Coefficient ring index: \\( 1 \\)
Twist minimal: no (minimal twist has level 68)
Projective image:\\(D_{4}\\)
Projective field:Galois closure of 4.2.19652.1
Artin image:$C_4\\wr C_2\\times C_6$
Artin field:Galois closure of \\(\\mathbb{Q}[x]/(x^{48} - \\cdots)\\)
", "content": {"html": "
Self dualno
Analytic conductor\\(1.66288462209\\)
Analytic rank\\(0\\)
Dimension\\(4\\)
Coefficient field\\(\\Q(\\zeta_{12})\\)
gp:\u00a0f.mod \\\\ as an extension of the character field
Defining polynomial\\( x^{4} - x^{2} + 1 \\)
Coefficient ring\\(\\Z[a_1, a_2]\\)
Coefficient ring index\\( 1 \\)
Twist minimalno (minimal twist has level 68)
Projective image\\(D_{4}\\)
Projective fieldGalois closure of<br>4.2.19652.1
Artin image$C_4\\wr C_2\\times C_6$
Artin fieldGalois closure of<br>\\(\\mathbb{Q}[x]/(x^{48} - \\cdots)\\)
", "is_complex": true, "table_nest_level": "1"}}, {"type": "title", "raw_content": "

Embedding invariants

", "content": {"title_content": "Embedding invariants", "level": "2"}}, {"type": "table", "raw_content": "
Embedding label 2027.1
Root\\(0.866025 - 0.500000i\\) of defining polynomial
Character\\(\\chi\\)\\(=\\)3332.2027
Dual form3332.1.bc.b.863.1
", "content": {"html": "
Embedding label2027.1
Root\\(0.866025 - 0.500000i\\) of defining polynomial
Character\\(\\chi\\)\\(=\\)3332.2027
Dual form3332.1.bc.b.863.1
", "is_complex": false, "table_nest_level": "1"}}, {"type": "paragraph", "raw_content": "
sage:\u00a0f.q_expansion() # note that sage often uses an isomorphic number field
", "content": [{"c": "sage:\u00a0f.q_expansion() # note that sage often uses an isomorphic number field", "t": "text"}]}, {"type": "paragraph", "raw_content": "
gp:\u00a0mfcoefs(f, 20)
", "content": [{"c": "gp:\u00a0mfcoefs(f, 20)", "t": "text"}]}, {"type": "table", "raw_content": "
\\(f(q)\\)\\(=\\)\\(q+(-0.866025 + 0.500000i) q^{2} +(0.500000 - 0.866025i) q^{4} +(-1.36603 - 0.366025i) q^{5} +1.00000i q^{8} +(-0.866025 + 0.500000i) q^{9} +(1.36603 - 0.366025i) q^{10} +(-0.500000 - 0.866025i) q^{16} +(-0.500000 + 0.866025i) q^{17} +(0.500000 - 0.866025i) q^{18} +(-1.00000 + 1.00000i) q^{20} +(0.866025 + 0.500000i) q^{25} +(1.00000 - 1.00000i) q^{29} +(0.866025 + 0.500000i) q^{32} -1.00000i q^{34} +1.00000i q^{36} +(1.36603 + 0.366025i) q^{37} +(0.366025 - 1.36603i) q^{40} +(-1.00000 - 1.00000i) q^{41} +(1.36603 - 0.366025i) q^{45} -1.00000 q^{50} +(-0.366025 + 1.36603i) q^{58} +(0.366025 - 1.36603i) q^{61} -1.00000 q^{64} +(0.500000 + 0.866025i) q^{68} +(-0.500000 - 0.866025i) q^{72} +(-0.366025 - 1.36603i) q^{73} +(-1.36603 + 0.366025i) q^{74} +(0.366025 + 1.36603i) q^{80} +(0.500000 - 0.866025i) q^{81} +(1.36603 + 0.366025i) q^{82} +(1.00000 - 1.00000i) q^{85} +(-1.00000 + 1.00000i) q^{90} +(1.00000 - 1.00000i) q^{97} +O(q^{100})\\)
\\(\\operatorname{Tr}(f)(q)\\)\\(=\\)\\( 4 q + 2 q^{4} - 2 q^{5} + 2 q^{10} - 2 q^{16} - 2 q^{17} + 2 q^{18} - 4 q^{20} + 4 q^{29} + 2 q^{37} - 2 q^{40} - 4 q^{41} + 2 q^{45} - 4 q^{50} + 2 q^{58} - 2 q^{61} - 4 q^{64} + 2 q^{68} - 2 q^{72} + 2 q^{73}+ \\cdots + 4 q^{97}+O(q^{100}) \\)\"Copy\"Toggle
", "content": {"html": "
\\(f(q)\\)\\(=\\)\\(q+(-0.866025 + 0.500000i) q^{2} +(0.500000 - 0.866025i) q^{4} +(-1.36603 - 0.366025i) q^{5} +1.00000i q^{8} +(-0.866025 + 0.500000i) q^{9} +(1.36603 - 0.366025i) q^{10} +(-0.500000 - 0.866025i) q^{16} +(-0.500000 + 0.866025i) q^{17} +(0.500000 - 0.866025i) q^{18} +(-1.00000 + 1.00000i) q^{20} +(0.866025 + 0.500000i) q^{25} +(1.00000 - 1.00000i) q^{29} +(0.866025 + 0.500000i) q^{32} -1.00000i q^{34} +1.00000i q^{36} +(1.36603 + 0.366025i) q^{37} +(0.366025 - 1.36603i) q^{40} +(-1.00000 - 1.00000i) q^{41} +(1.36603 - 0.366025i) q^{45} -1.00000 q^{50} +(-0.366025 + 1.36603i) q^{58} +(0.366025 - 1.36603i) q^{61} -1.00000 q^{64} +(0.500000 + 0.866025i) q^{68} +(-0.500000 - 0.866025i) q^{72} +(-0.366025 - 1.36603i) q^{73} +(-1.36603 + 0.366025i) q^{74} +(0.366025 + 1.36603i) q^{80} +(0.500000 - 0.866025i) q^{81} +(1.36603 + 0.366025i) q^{82} +(1.00000 - 1.00000i) q^{85} +(-1.00000 + 1.00000i) q^{90} +(1.00000 - 1.00000i) q^{97} +O(q^{100})\\)
\\(\\operatorname{Tr}(f)(q)\\)\\(=\\)\\( 4 q + 2 q^{4} - 2 q^{5} + 2 q^{10} - 2 q^{16} - 2 q^{17} + 2 q^{18} - 4 q^{20} + 4 q^{29} + 2 q^{37} - 2 q^{40} - 4 q^{41} + 2 q^{45} - 4 q^{50} + 2 q^{58} - 2 q^{61} - 4 q^{64} + 2 q^{68} - 2 q^{72} + 2 q^{73}+ \\cdots + 4 q^{97}+O(q^{100}) \\)
", "is_complex": false, "table_nest_level": "1"}}, {"type": "title", "raw_content": "

Character values

", "content": {"title_content": "Character values", "level": "2"}}, {"type": "paragraph", "raw_content": "

We give the values of \\chi on generators for \\left(\\mathbb{Z}/3332\\mathbb{Z}\\right)^\\times.

", "content": [{"c": "We give the values of", "t": "text"}, {"c": "\\chi", "t": "equation-inline"}, {"c": "on generators for", "t": "text"}, {"c": "\\left(\\mathbb{Z}/3332\\mathbb{Z}\\right)^\\times", "t": "equation-inline"}, {"c": ".", "t": "text"}]}, {"type": "table", "raw_content": "
\\(n\\)\\(785\\)\\(885\\)\\(1667\\)
\\(\\chi(n)\\)\\(e\\left(\\frac{3}{4}\\right)\\)\\(e\\left(\\frac{2}{3}\\right)\\)\\(-1\\)
", "content": {"html": "
\\(n\\)\\(785\\)\\(885\\)\\(1667\\)
\\(\\chi(n)\\)\\(e\\left(\\frac{3}{4}\\right)\\)\\(e\\left(\\frac{2}{3}\\right)\\)\\(-1\\)
", "is_complex": false, "table_nest_level": "1"}}, {"type": "title", "raw_content": "

Coefficient data

", "content": {"title_content": "Coefficient data", "level": "2"}}, {"type": "paragraph", "raw_content": "

For each \\(n\\) we display the coefficients of the \\(q\\)-expansion \\(a_n\\), the\nSatake parameters \\(\\alpha_p\\),\nand the Satake angles \\(\\theta_p = \\textrm{Arg}(\\alpha_p)\\).

", "content": [{"c": "For each \\(n\\) we display the coefficients of the \\(q\\)-expansion \\(a_n\\), the Satake parameters\\(\\alpha_p\\),\nand the Satake angles \\(\\theta_p = \\textrm{Arg}(\\alpha_p)\\).", "t": "text"}]}, {"type": "paragraph", "raw_content": "
\n (See \\(a_n\\) instead)\n
", "content": [{"c": "( See \\(a_n\\) instead)", "t": "text"}]}, {"type": "paragraph", "raw_content": "
\n (See \\(a_n\\) instead)\n
", "content": [{"c": "( See \\(a_n\\) instead)", "t": "text"}]}, {"type": "paragraph", "raw_content": "
\n (See \\(a_n\\) instead)\n
", "content": [{"c": "( See \\(a_n\\) instead)", "t": "text"}]}, {"type": "paragraph", "raw_content": "
\n (See only \\(a_p\\))\n
", "content": [{"c": "( See only \\(a_p\\))", "t": "text"}]}, {"type": "paragraph", "raw_content": "
\n (See only \\(a_p\\))\n
", "content": [{"c": "( See only \\(a_p\\))", "t": "text"}]}, {"type": "paragraph", "raw_content": "
\n (See only \\(a_p\\))\n
", "content": [{"c": "( See only \\(a_p\\))", "t": "text"}]}, {"type": "table", "raw_content": "
\n \\(n\\)\n \n \\(a_n\\)\n \n \\(a_n / n^{(k-1)/2}\\)\n \n \\( \\alpha_n \\)\n \n \\( \\theta_n \\)\n
\n \\(p\\)\n \n \\(a_p\\)\n \n \\(a_p / p^{(k-1)/2}\\)\n \n \\( \\alpha_p\\)\n \n \\( \\theta_p \\)\n
\n \\(2\\)\n \n \u22120.866025\n \n +\n \n 0.500000i\n \u22120.866025\n \n +\n \n 0.500000i
\n \\(3\\)\n \n 0\n \n 0\n \n \u22120.258819\n \n \u2212\n \n 0.965926i\n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \\(0.416667\\pi\\)\n
\n \\(4\\)\n \n 0.500000\n \n \u2212\n \n 0.866025i\n 0.500000\n \n \u2212\n \n 0.866025i
\n \\(5\\)\n \n \u22121.36603\n \n \u2212\n \n 0.366025i\n \u22121.36603\n \n \u2212\n \n 0.366025i\n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(6\\)\n \n 0\n \n 0\n
\n \\(7\\)\n \n 0\n \n 0\n
\n \\(8\\)\n \n 1.00000i\n 1.00000i
\n \\(9\\)\n \n \u22120.866025\n \n +\n \n 0.500000i\n \u22120.866025\n \n +\n \n 0.500000i
\n \\(10\\)\n \n 1.36603\n \n \u2212\n \n 0.366025i\n 1.36603\n \n \u2212\n \n 0.366025i
\n \\(11\\)\n \n 0\n \n 0\n \n 0.965926\n \n \u2212\n \n 0.258819i\n \\(-0.0833333\\pi\\)\n
\n \u22120.965926\n \n +\n \n 0.258819i\n \\(0.916667\\pi\\)\n
\n \\(12\\)\n \n 0\n \n 0\n
\n \\(13\\)\n \n 0\n \n 0\n \n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(14\\)\n \n 0\n \n 0\n
\n \\(15\\)\n \n 0\n \n 0\n
\n \\(16\\)\n \n \u22120.500000\n \n \u2212\n \n 0.866025i\n \u22120.500000\n \n \u2212\n \n 0.866025i
\n \\(17\\)\n \n \u22120.500000\n \n +\n \n 0.866025i\n \u22120.500000\n \n +\n \n 0.866025i
\n \\(18\\)\n \n 0.500000\n \n \u2212\n \n 0.866025i\n 0.500000\n \n \u2212\n \n 0.866025i
\n \\(19\\)\n \n 0\n \n 0\n \n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(20\\)\n \n \u22121.00000\n \n +\n \n 1.00000i\n \u22121.00000\n \n +\n \n 1.00000i
\n \\(21\\)\n \n 0\n \n 0\n
\n \\(22\\)\n \n 0\n \n 0\n
\n \\(23\\)\n \n 0\n \n 0\n \n 0.258819\n \n \u2212\n \n 0.965926i\n \\(-0.416667\\pi\\)\n
\n \u22120.258819\n \n +\n \n 0.965926i\n \\(0.583333\\pi\\)\n
\n \\(24\\)\n \n 0\n \n 0\n
\n \\(25\\)\n \n 0.866025\n \n +\n \n 0.500000i\n 0.866025\n \n +\n \n 0.500000i
\n \\(26\\)\n \n 0\n \n 0\n
\n \\(27\\)\n \n 0\n \n 0\n
\n \\(28\\)\n \n 0\n \n 0\n
\n \\(29\\)\n \n 1.00000\n \n \u2212\n \n 1.00000i\n 1.00000\n \n \u2212\n \n 1.00000i\n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000\n \n \\(0\\)\n
\n \\(30\\)\n \n 0\n \n 0\n
\n \\(31\\)\n \n 0\n \n 0\n \n \u22120.258819\n \n \u2212\n \n 0.965926i\n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \\(0.416667\\pi\\)\n
\n \\(32\\)\n \n 0.866025\n \n +\n \n 0.500000i\n 0.866025\n \n +\n \n 0.500000i
\n \\(33\\)\n \n 0\n \n 0\n
\n \\(34\\)\n \n \u2212\n \n 1.00000i\n \u2212\n \n 1.00000i
\n \\(35\\)\n \n 0\n \n 0\n
\n \\(36\\)\n \n 1.00000i\n 1.00000i
\n \\(37\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i\n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(38\\)\n \n 0\n \n 0\n
\n \\(39\\)\n \n 0\n \n 0\n
\n \\(40\\)\n \n 0.366025\n \n \u2212\n \n 1.36603i\n 0.366025\n \n \u2212\n \n 1.36603i
\n \\(41\\)\n \n \u22121.00000\n \n \u2212\n \n 1.00000i\n \u22121.00000\n \n \u2212\n \n 1.00000i\n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(42\\)\n \n 0\n \n 0\n
\n \\(43\\)\n \n 0\n \n 0\n \n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(44\\)\n \n 0\n \n 0\n
\n \\(45\\)\n \n 1.36603\n \n \u2212\n \n 0.366025i\n 1.36603\n \n \u2212\n \n 0.366025i
\n \\(46\\)\n \n 0\n \n 0\n
\n \\(47\\)\n \n 0\n \n 0\n \n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(48\\)\n \n 0\n \n 0\n
\n \\(49\\)\n \n 0\n \n 0\n
\n \\(50\\)\n \n \u22121.00000\n \n \u22121.00000\n
\n \\(51\\)\n \n 0\n \n 0\n
\n \\(52\\)\n \n 0\n \n 0\n
\n \\(53\\)\n \n 0\n \n 0\n \n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n \u22120.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(54\\)\n \n 0\n \n 0\n
\n \\(55\\)\n \n 0\n \n 0\n
\n \\(56\\)\n \n 0\n \n 0\n
\n \\(57\\)\n \n 0\n \n 0\n
\n \\(58\\)\n \n \u22120.366025\n \n +\n \n 1.36603i\n \u22120.366025\n \n +\n \n 1.36603i
\n \\(59\\)\n \n 0\n \n 0\n \n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(60\\)\n \n 0\n \n 0\n
\n \\(61\\)\n \n 0.366025\n \n \u2212\n \n 1.36603i\n 0.366025\n \n \u2212\n \n 1.36603i\n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \\(62\\)\n \n 0\n \n 0\n
\n \\(63\\)\n \n 0\n \n 0\n
\n \\(64\\)\n \n \u22121.00000\n \n \u22121.00000\n
\n \\(65\\)\n \n 0\n \n 0\n
\n \\(66\\)\n \n 0\n \n 0\n
\n \\(67\\)\n \n 0\n \n 0\n \n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n \u22120.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(68\\)\n \n 0.500000\n \n +\n \n 0.866025i\n 0.500000\n \n +\n \n 0.866025i
\n \\(69\\)\n \n 0\n \n 0\n
\n \\(70\\)\n \n 0\n \n 0\n
\n \\(71\\)\n \n 0\n \n 0\n \n 0.707107\n \n \u2212\n \n 0.707107i\n \\(-0.250000\\pi\\)\n
\n \u22120.707107\n \n +\n \n 0.707107i\n \\(0.750000\\pi\\)\n
\n \\(72\\)\n \n \u22120.500000\n \n \u2212\n \n 0.866025i\n \u22120.500000\n \n \u2212\n \n 0.866025i
\n \\(73\\)\n \n \u22120.366025\n \n \u2212\n \n 1.36603i\n \u22120.366025\n \n \u2212\n \n 1.36603i\n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n \\(74\\)\n \n \u22121.36603\n \n +\n \n 0.366025i\n \u22121.36603\n \n +\n \n 0.366025i
\n \\(75\\)\n \n 0\n \n 0\n
\n \\(76\\)\n \n 0\n \n 0\n
\n \\(77\\)\n \n 0\n \n 0\n
\n \\(78\\)\n \n 0\n \n 0\n
\n \\(79\\)\n \n 0\n \n 0\n \n 0.258819\n \n \u2212\n \n 0.965926i\n \\(-0.416667\\pi\\)\n
\n \u22120.258819\n \n +\n \n 0.965926i\n \\(0.583333\\pi\\)\n
\n \\(80\\)\n \n 0.366025\n \n +\n \n 1.36603i\n 0.366025\n \n +\n \n 1.36603i
\n \\(81\\)\n \n 0.500000\n \n \u2212\n \n 0.866025i\n 0.500000\n \n \u2212\n \n 0.866025i
\n \\(82\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i
\n \\(83\\)\n \n 0\n \n 0\n \n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(84\\)\n \n 0\n \n 0\n
\n \\(85\\)\n \n 1.00000\n \n \u2212\n \n 1.00000i\n 1.00000\n \n \u2212\n \n 1.00000i
\n \\(86\\)\n \n 0\n \n 0\n
\n \\(87\\)\n \n 0\n \n 0\n
\n \\(88\\)\n \n 0\n \n 0\n
\n \\(89\\)\n \n 0\n \n 0\n \n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(90\\)\n \n \u22121.00000\n \n +\n \n 1.00000i\n \u22121.00000\n \n +\n \n 1.00000i
\n \\(91\\)\n \n 0\n \n 0\n
\n \\(92\\)\n \n 0\n \n 0\n
\n \\(93\\)\n \n 0\n \n 0\n
\n \\(94\\)\n \n 0\n \n 0\n
\n \\(95\\)\n \n 0\n \n 0\n
\n \\(96\\)\n \n 0\n \n 0\n
\n \\(97\\)\n \n 1.00000\n \n \u2212\n \n 1.00000i\n 1.00000\n \n \u2212\n \n 1.00000i\n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000\n \n \\(0\\)\n
\n \\(98\\)\n \n 0\n \n 0\n
\n \\(99\\)\n \n 0\n \n 0\n
\n \\(100\\)\n \n 0.866025\n \n \u2212\n \n 0.500000i\n 0.866025\n \n \u2212\n \n 0.500000i
\n \\(101\\)\n \n 0\n \n 0\n \n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(102\\)\n \n 0\n \n 0\n
\n \\(103\\)\n \n 0\n \n 0\n \n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(104\\)\n \n 0\n \n 0\n
\n \\(105\\)\n \n 0\n \n 0\n
\n \\(106\\)\n \n 0\n \n 0\n
\n \\(107\\)\n \n 0\n \n 0\n \n \u22120.965926\n \n \u2212\n \n 0.258819i\n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \\(0.0833333\\pi\\)\n
\n \\(108\\)\n \n 0\n \n 0\n
\n \\(109\\)\n \n 1.36603\n \n \u2212\n \n 0.366025i\n 1.36603\n \n \u2212\n \n 0.366025i\n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(110\\)\n \n 0\n \n 0\n
\n \\(111\\)\n \n 0\n \n 0\n
\n \\(112\\)\n \n 0\n \n 0\n
\n \\(113\\)\n \n \u22121.00000\n \n \u2212\n \n 1.00000i\n \u22121.00000\n \n \u2212\n \n 1.00000i\n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(114\\)\n \n 0\n \n 0\n
\n \\(115\\)\n \n 0\n \n 0\n
\n \\(116\\)\n \n \u22120.366025\n \n \u2212\n \n 1.36603i\n \u22120.366025\n \n \u2212\n \n 1.36603i
\n \\(117\\)\n \n 0\n \n 0\n
\n \\(118\\)\n \n 0\n \n 0\n
\n \\(119\\)\n \n 0\n \n 0\n
\n \\(120\\)\n \n 0\n \n 0\n
\n \\(121\\)\n \n 0.866025\n \n \u2212\n \n 0.500000i\n 0.866025\n \n \u2212\n \n 0.500000i
\n \\(122\\)\n \n 0.366025\n \n +\n \n 1.36603i\n 0.366025\n \n +\n \n 1.36603i
\n \\(123\\)\n \n 0\n \n 0\n
\n \\(124\\)\n \n 0\n \n 0\n
\n \\(125\\)\n \n 0\n \n 0\n
\n \\(126\\)\n \n 0\n \n 0\n
\n \\(127\\)\n \n 0\n \n 0\n \n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(128\\)\n \n 0.866025\n \n \u2212\n \n 0.500000i\n 0.866025\n \n \u2212\n \n 0.500000i
\n \\(129\\)\n \n 0\n \n 0\n
\n \\(130\\)\n \n 0\n \n 0\n
\n \\(131\\)\n \n 0\n \n 0\n \n \u22120.965926\n \n \u2212\n \n 0.258819i\n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \\(0.0833333\\pi\\)\n
\n \\(132\\)\n \n 0\n \n 0\n
\n \\(133\\)\n \n 0\n \n 0\n
\n \\(134\\)\n \n 0\n \n 0\n
\n \\(135\\)\n \n 0\n \n 0\n
\n \\(136\\)\n \n \u22120.866025\n \n \u2212\n \n 0.500000i\n \u22120.866025\n \n \u2212\n \n 0.500000i
\n \\(137\\)\n \n 0\n \n 0\n \n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(138\\)\n \n 0\n \n 0\n
\n \\(139\\)\n \n 0\n \n 0\n \n 0.707107\n \n \u2212\n \n 0.707107i\n \\(-0.250000\\pi\\)\n
\n \u22120.707107\n \n +\n \n 0.707107i\n \\(0.750000\\pi\\)\n
\n \\(140\\)\n \n 0\n \n 0\n
\n \\(141\\)\n \n 0\n \n 0\n
\n \\(142\\)\n \n 0\n \n 0\n
\n \\(143\\)\n \n 0\n \n 0\n
\n \\(144\\)\n \n 0.866025\n \n +\n \n 0.500000i\n 0.866025\n \n +\n \n 0.500000i
\n \\(145\\)\n \n \u22121.73205\n \n +\n \n 1.00000i\n \u22121.73205\n \n +\n \n 1.00000i
\n \\(146\\)\n \n 1.00000\n \n +\n \n 1.00000i\n 1.00000\n \n +\n \n 1.00000i
\n \\(147\\)\n \n 0\n \n 0\n
\n \\(148\\)\n \n 1.00000\n \n \u2212\n \n 1.00000i\n 1.00000\n \n \u2212\n \n 1.00000i
\n \\(149\\)\n \n \u22121.00000\n \n \u2212\n \n 1.73205i\n \u22121.00000\n \n \u2212\n \n 1.73205i\n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n \\(150\\)\n \n 0\n \n 0\n
\n \\(151\\)\n \n 0\n \n 0\n \n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(152\\)\n \n 0\n \n 0\n
\n \\(153\\)\n \n \u2212\n \n 1.00000i\n \u2212\n \n 1.00000i
\n \\(154\\)\n \n 0\n \n 0\n
\n \\(155\\)\n \n 0\n \n 0\n
\n \\(156\\)\n \n 0\n \n 0\n
\n \\(157\\)\n \n 1.00000\n \n \u2212\n \n 1.73205i\n 1.00000\n \n \u2212\n \n 1.73205i\n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n \\(158\\)\n \n 0\n \n 0\n
\n \\(159\\)\n \n 0\n \n 0\n
\n \\(160\\)\n \n \u22121.00000\n \n \u2212\n \n 1.00000i\n \u22121.00000\n \n \u2212\n \n 1.00000i
\n \\(161\\)\n \n 0\n \n 0\n
\n \\(162\\)\n \n 1.00000i\n 1.00000i
\n \\(163\\)\n \n 0\n \n 0\n \n 0.258819\n \n \u2212\n \n 0.965926i\n \\(-0.416667\\pi\\)\n
\n \u22120.258819\n \n +\n \n 0.965926i\n \\(0.583333\\pi\\)\n
\n \\(164\\)\n \n \u22121.36603\n \n +\n \n 0.366025i\n \u22121.36603\n \n +\n \n 0.366025i
\n \\(165\\)\n \n 0\n \n 0\n
\n \\(166\\)\n \n 0\n \n 0\n
\n \\(167\\)\n \n 0\n \n 0\n \n 0.707107\n \n \u2212\n \n 0.707107i\n \\(-0.250000\\pi\\)\n
\n \u22120.707107\n \n +\n \n 0.707107i\n \\(0.750000\\pi\\)\n
\n \\(168\\)\n \n 0\n \n 0\n
\n \\(169\\)\n \n \u22121.00000\n \n \u22121.00000\n
\n \\(170\\)\n \n \u22120.366025\n \n +\n \n 1.36603i\n \u22120.366025\n \n +\n \n 1.36603i
\n \\(171\\)\n \n 0\n \n 0\n
\n \\(172\\)\n \n 0\n \n 0\n
\n \\(173\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i\n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(174\\)\n \n 0\n \n 0\n
\n \\(175\\)\n \n 0\n \n 0\n
\n \\(176\\)\n \n 0\n \n 0\n
\n \\(177\\)\n \n 0\n \n 0\n
\n \\(178\\)\n \n 0\n \n 0\n
\n \\(179\\)\n \n 0\n \n 0\n \n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(180\\)\n \n 0.366025\n \n \u2212\n \n 1.36603i\n 0.366025\n \n \u2212\n \n 1.36603i
\n \\(181\\)\n \n 1.00000\n \n +\n \n 1.00000i\n 1.00000\n \n +\n \n 1.00000i\n 1.00000\n \n \\(0\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(182\\)\n \n 0\n \n 0\n
\n \\(183\\)\n \n 0\n \n 0\n
\n \\(184\\)\n \n 0\n \n 0\n
\n \\(185\\)\n \n \u22121.73205\n \n \u2212\n \n 1.00000i\n \u22121.73205\n \n \u2212\n \n 1.00000i
\n \\(186\\)\n \n 0\n \n 0\n
\n \\(187\\)\n \n 0\n \n 0\n
\n \\(188\\)\n \n 0\n \n 0\n
\n \\(189\\)\n \n 0\n \n 0\n
\n \\(190\\)\n \n 0\n \n 0\n
\n \\(191\\)\n \n 0\n \n 0\n \n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(192\\)\n \n 0\n \n 0\n
\n \\(193\\)\n \n \u22121.36603\n \n +\n \n 0.366025i\n \u22121.36603\n \n +\n \n 0.366025i\n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n \u22120.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(194\\)\n \n \u22120.366025\n \n +\n \n 1.36603i\n \u22120.366025\n \n +\n \n 1.36603i
\n \\(195\\)\n \n 0\n \n 0\n
\n \\(196\\)\n \n 0\n \n 0\n
\n \\(197\\)\n \n 1.00000\n \n +\n \n 1.00000i\n 1.00000\n \n +\n \n 1.00000i\n 1.00000\n \n \\(0\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(198\\)\n \n 0\n \n 0\n
\n \\(199\\)\n \n 0\n \n 0\n \n \u22120.258819\n \n \u2212\n \n 0.965926i\n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \\(0.416667\\pi\\)\n
\n \\(200\\)\n \n \u22120.500000\n \n +\n \n 0.866025i\n \u22120.500000\n \n +\n \n 0.866025i
\n \\(201\\)\n \n 0\n \n 0\n
\n \\(202\\)\n \n 0\n \n 0\n
\n \\(203\\)\n \n 0\n \n 0\n
\n \\(204\\)\n \n 0\n \n 0\n
\n \\(205\\)\n \n 1.00000\n \n +\n \n 1.73205i\n 1.00000\n \n +\n \n 1.73205i
\n \\(206\\)\n \n 0\n \n 0\n
\n \\(207\\)\n \n 0\n \n 0\n
\n \\(208\\)\n \n 0\n \n 0\n
\n \\(209\\)\n \n 0\n \n 0\n
\n \\(210\\)\n \n 0\n \n 0\n
\n \\(211\\)\n \n 0\n \n 0\n \n \u22120.707107\n \n \u2212\n \n 0.707107i\n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \\(0.250000\\pi\\)\n
\n \\(212\\)\n \n 0\n \n 0\n
\n \\(213\\)\n \n 0\n \n 0\n
\n \\(214\\)\n \n 0\n \n 0\n
\n \\(215\\)\n \n 0\n \n 0\n
\n \\(216\\)\n \n 0\n \n 0\n
\n \\(217\\)\n \n 0\n \n 0\n
\n \\(218\\)\n \n \u22121.00000\n \n +\n \n 1.00000i\n \u22121.00000\n \n +\n \n 1.00000i
\n \\(219\\)\n \n 0\n \n 0\n
\n \\(220\\)\n \n 0\n \n 0\n
\n \\(221\\)\n \n 0\n \n 0\n
\n \\(222\\)\n \n 0\n \n 0\n
\n \\(223\\)\n \n 0\n \n 0\n \n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(224\\)\n \n 0\n \n 0\n
\n \\(225\\)\n \n \u22121.00000\n \n \u22121.00000\n
\n \\(226\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i
\n \\(227\\)\n \n 0\n \n 0\n \n 0.965926\n \n \u2212\n \n 0.258819i\n \\(-0.0833333\\pi\\)\n
\n \u22120.965926\n \n +\n \n 0.258819i\n \\(0.916667\\pi\\)\n
\n \\(228\\)\n \n 0\n \n 0\n
\n \\(229\\)\n \n \u22121.73205\n \n +\n \n 1.00000i\n \u22121.73205\n \n +\n \n 1.00000i\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(230\\)\n \n 0\n \n 0\n
\n \\(231\\)\n \n 0\n \n 0\n
\n \\(232\\)\n \n 1.00000\n \n +\n \n 1.00000i\n 1.00000\n \n +\n \n 1.00000i
\n \\(233\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i\n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(234\\)\n \n 0\n \n 0\n
\n \\(235\\)\n \n 0\n \n 0\n
\n \\(236\\)\n \n 0\n \n 0\n
\n \\(237\\)\n \n 0\n \n 0\n
\n \\(238\\)\n \n 0\n \n 0\n
\n \\(239\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(240\\)\n \n 0\n \n 0\n
\n \\(241\\)\n \n \u22120.366025\n \n \u2212\n \n 1.36603i\n \u22120.366025\n \n \u2212\n \n 1.36603i\n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n \\(242\\)\n \n \u22120.500000\n \n +\n \n 0.866025i\n \u22120.500000\n \n +\n \n 0.866025i
\n \\(243\\)\n \n 0\n \n 0\n
\n \\(244\\)\n \n \u22121.00000\n \n \u2212\n \n 1.00000i\n \u22121.00000\n \n \u2212\n \n 1.00000i
\n \\(245\\)\n \n 0\n \n 0\n
\n \\(246\\)\n \n 0\n \n 0\n
\n \\(247\\)\n \n 0\n \n 0\n
\n \\(248\\)\n \n 0\n \n 0\n
\n \\(249\\)\n \n 0\n \n 0\n
\n \\(250\\)\n \n 0\n \n 0\n
\n \\(251\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(252\\)\n \n 0\n \n 0\n
\n \\(253\\)\n \n 0\n \n 0\n
\n \\(254\\)\n \n 0\n \n 0\n
\n \\(255\\)\n \n 0\n \n 0\n
\n \\(256\\)\n \n \u22120.500000\n \n +\n \n 0.866025i\n \u22120.500000\n \n +\n \n 0.866025i
\n \\(257\\)\n \n 1.73205\n \n \u2212\n \n 1.00000i\n 1.73205\n \n \u2212\n \n 1.00000i\n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \\(258\\)\n \n 0\n \n 0\n
\n \\(259\\)\n \n 0\n \n 0\n
\n \\(260\\)\n \n 0\n \n 0\n
\n \\(261\\)\n \n \u22120.366025\n \n +\n \n 1.36603i\n \u22120.366025\n \n +\n \n 1.36603i
\n \\(262\\)\n \n 0\n \n 0\n
\n \\(263\\)\n \n 0\n \n 0\n \n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(264\\)\n \n 0\n \n 0\n
\n \\(265\\)\n \n 0\n \n 0\n
\n \\(266\\)\n \n 0\n \n 0\n
\n \\(267\\)\n \n 0\n \n 0\n
\n \\(268\\)\n \n 0\n \n 0\n
\n \\(269\\)\n \n 0.366025\n \n +\n \n 1.36603i\n 0.366025\n \n +\n \n 1.36603i\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \u22120.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(270\\)\n \n 0\n \n 0\n
\n \\(271\\)\n \n 0\n \n 0\n \n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(272\\)\n \n 1.00000\n \n 1.00000\n
\n \\(273\\)\n \n 0\n \n 0\n
\n \\(274\\)\n \n 0\n \n 0\n
\n \\(275\\)\n \n 0\n \n 0\n
\n \\(276\\)\n \n 0\n \n 0\n
\n \\(277\\)\n \n 0.366025\n \n +\n \n 1.36603i\n 0.366025\n \n +\n \n 1.36603i\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \u22120.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(278\\)\n \n 0\n \n 0\n
\n \\(279\\)\n \n 0\n \n 0\n
\n \\(280\\)\n \n 0\n \n 0\n
\n \\(281\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(282\\)\n \n 0\n \n 0\n
\n \\(283\\)\n \n 0\n \n 0\n \n 0.965926\n \n \u2212\n \n 0.258819i\n \\(-0.0833333\\pi\\)\n
\n \u22120.965926\n \n +\n \n 0.258819i\n \\(0.916667\\pi\\)\n
\n \\(284\\)\n \n 0\n \n 0\n
\n \\(285\\)\n \n 0\n \n 0\n
\n \\(286\\)\n \n 0\n \n 0\n
\n \\(287\\)\n \n 0\n \n 0\n
\n \\(288\\)\n \n \u22121.00000\n \n \u22121.00000\n
\n \\(289\\)\n \n \u22120.500000\n \n \u2212\n \n 0.866025i\n \u22120.500000\n \n \u2212\n \n 0.866025i
\n \\(290\\)\n \n 1.00000\n \n \u2212\n \n 1.73205i\n 1.00000\n \n \u2212\n \n 1.73205i
\n \\(291\\)\n \n 0\n \n 0\n
\n \\(292\\)\n \n \u22121.36603\n \n \u2212\n \n 0.366025i\n \u22121.36603\n \n \u2212\n \n 0.366025i
\n \\(293\\)\n \n 2.00000\n \n 2.00000\n \n 1.00000\n \n \\(0\\)\n
\n 1.00000\n \n \\(0\\)\n
\n \\(294\\)\n \n 0\n \n 0\n
\n \\(295\\)\n \n 0\n \n 0\n
\n \\(296\\)\n \n \u22120.366025\n \n +\n \n 1.36603i\n \u22120.366025\n \n +\n \n 1.36603i
\n \\(297\\)\n \n 0\n \n 0\n
\n \\(298\\)\n \n 1.73205\n \n +\n \n 1.00000i\n 1.73205\n \n +\n \n 1.00000i
\n \\(299\\)\n \n 0\n \n 0\n
\n \\(300\\)\n \n 0\n \n 0\n
\n \\(301\\)\n \n 0\n \n 0\n
\n \\(302\\)\n \n 0\n \n 0\n
\n \\(303\\)\n \n 0\n \n 0\n
\n \\(304\\)\n \n 0\n \n 0\n
\n \\(305\\)\n \n \u22121.00000\n \n +\n \n 1.73205i\n \u22121.00000\n \n +\n \n 1.73205i
\n \\(306\\)\n \n 0.500000\n \n +\n \n 0.866025i\n 0.500000\n \n +\n \n 0.866025i
\n \\(307\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(308\\)\n \n 0\n \n 0\n
\n \\(309\\)\n \n 0\n \n 0\n
\n \\(310\\)\n \n 0\n \n 0\n
\n \\(311\\)\n \n 0\n \n 0\n \n \u22120.258819\n \n \u2212\n \n 0.965926i\n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \\(0.416667\\pi\\)\n
\n \\(312\\)\n \n 0\n \n 0\n
\n \\(313\\)\n \n \u22120.366025\n \n +\n \n 1.36603i\n \u22120.366025\n \n +\n \n 1.36603i\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(314\\)\n \n 2.00000i\n 2.00000i
\n \\(315\\)\n \n 0\n \n 0\n
\n \\(316\\)\n \n 0\n \n 0\n
\n \\(317\\)\n \n 0.366025\n \n \u2212\n \n 1.36603i\n 0.366025\n \n \u2212\n \n 1.36603i\n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \\(318\\)\n \n 0\n \n 0\n
\n \\(319\\)\n \n 0\n \n 0\n
\n \\(320\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i
\n \\(321\\)\n \n 0\n \n 0\n
\n \\(322\\)\n \n 0\n \n 0\n
\n \\(323\\)\n \n 0\n \n 0\n
\n \\(324\\)\n \n \u22120.500000\n \n \u2212\n \n 0.866025i\n \u22120.500000\n \n \u2212\n \n 0.866025i
\n \\(325\\)\n \n 0\n \n 0\n
\n \\(326\\)\n \n 0\n \n 0\n
\n \\(327\\)\n \n 0\n \n 0\n
\n \\(328\\)\n \n 1.00000\n \n \u2212\n \n 1.00000i\n 1.00000\n \n \u2212\n \n 1.00000i
\n \\(329\\)\n \n 0\n \n 0\n
\n \\(330\\)\n \n 0\n \n 0\n
\n \\(331\\)\n \n 0\n \n 0\n \n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(332\\)\n \n 0\n \n 0\n
\n \\(333\\)\n \n \u22121.36603\n \n +\n \n 0.366025i\n \u22121.36603\n \n +\n \n 0.366025i
\n \\(334\\)\n \n 0\n \n 0\n
\n \\(335\\)\n \n 0\n \n 0\n
\n \\(336\\)\n \n 0\n \n 0\n
\n \\(337\\)\n \n 1.00000\n \n \u2212\n \n 1.00000i\n 1.00000\n \n \u2212\n \n 1.00000i\n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000\n \n \\(0\\)\n
\n \\(338\\)\n \n 0.866025\n \n \u2212\n \n 0.500000i\n 0.866025\n \n \u2212\n \n 0.500000i
\n \\(339\\)\n \n 0\n \n 0\n
\n \\(340\\)\n \n \u22120.366025\n \n \u2212\n \n 1.36603i\n \u22120.366025\n \n \u2212\n \n 1.36603i
\n \\(341\\)\n \n 0\n \n 0\n
\n \\(342\\)\n \n 0\n \n 0\n
\n \\(343\\)\n \n 0\n \n 0\n
\n \\(344\\)\n \n 0\n \n 0\n
\n \\(345\\)\n \n 0\n \n 0\n
\n \\(346\\)\n \n \u22121.36603\n \n +\n \n 0.366025i\n \u22121.36603\n \n +\n \n 0.366025i
\n \\(347\\)\n \n 0\n \n 0\n \n 0.965926\n \n \u2212\n \n 0.258819i\n \\(-0.0833333\\pi\\)\n
\n \u22120.965926\n \n +\n \n 0.258819i\n \\(0.916667\\pi\\)\n
\n \\(348\\)\n \n 0\n \n 0\n
\n \\(349\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(350\\)\n \n 0\n \n 0\n
\n \\(351\\)\n \n 0\n \n 0\n
\n \\(352\\)\n \n 0\n \n 0\n
\n \\(353\\)\n \n \u22121.00000\n \n +\n \n 1.73205i\n \u22121.00000\n \n +\n \n 1.73205i\n \u22120.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \u22120.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(354\\)\n \n 0\n \n 0\n
\n \\(355\\)\n \n 0\n \n 0\n
\n \\(356\\)\n \n 0\n \n 0\n
\n \\(357\\)\n \n 0\n \n 0\n
\n \\(358\\)\n \n 0\n \n 0\n
\n \\(359\\)\n \n 0\n \n 0\n \n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(360\\)\n \n 0.366025\n \n +\n \n 1.36603i\n 0.366025\n \n +\n \n 1.36603i
\n \\(361\\)\n \n 0.500000\n \n \u2212\n \n 0.866025i\n 0.500000\n \n \u2212\n \n 0.866025i
\n \\(362\\)\n \n \u22121.36603\n \n \u2212\n \n 0.366025i\n \u22121.36603\n \n \u2212\n \n 0.366025i
\n \\(363\\)\n \n 0\n \n 0\n
\n \\(364\\)\n \n 0\n \n 0\n
\n \\(365\\)\n \n 2.00000i\n 2.00000i
\n \\(366\\)\n \n 0\n \n 0\n
\n \\(367\\)\n \n 0\n \n 0\n \n 0.965926\n \n \u2212\n \n 0.258819i\n \\(-0.0833333\\pi\\)\n
\n \u22120.965926\n \n +\n \n 0.258819i\n \\(0.916667\\pi\\)\n
\n \\(368\\)\n \n 0\n \n 0\n
\n \\(369\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i
\n \\(370\\)\n \n 2.00000\n \n 2.00000\n
\n \\(371\\)\n \n 0\n \n 0\n
\n \\(372\\)\n \n 0\n \n 0\n
\n \\(373\\)\n \n 0\n \n 0\n \n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(374\\)\n \n 0\n \n 0\n
\n \\(375\\)\n \n 0\n \n 0\n
\n \\(376\\)\n \n 0\n \n 0\n
\n \\(377\\)\n \n 0\n \n 0\n
\n \\(378\\)\n \n 0\n \n 0\n
\n \\(379\\)\n \n 0\n \n 0\n \n 0.707107\n \n \u2212\n \n 0.707107i\n \\(-0.250000\\pi\\)\n
\n \u22120.707107\n \n +\n \n 0.707107i\n \\(0.750000\\pi\\)\n
\n \\(380\\)\n \n 0\n \n 0\n
\n \\(381\\)\n \n 0\n \n 0\n
\n \\(382\\)\n \n 0\n \n 0\n
\n \\(383\\)\n \n 0\n \n 0\n \n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(384\\)\n \n 0\n \n 0\n
\n \\(385\\)\n \n 0\n \n 0\n
\n \\(386\\)\n \n 1.00000\n \n \u2212\n \n 1.00000i\n 1.00000\n \n \u2212\n \n 1.00000i
\n \\(387\\)\n \n 0\n \n 0\n
\n \\(388\\)\n \n \u22120.366025\n \n \u2212\n \n 1.36603i\n \u22120.366025\n \n \u2212\n \n 1.36603i
\n \\(389\\)\n \n \u22121.73205\n \n \u2212\n \n 1.00000i\n \u22121.73205\n \n \u2212\n \n 1.00000i\n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n \\(390\\)\n \n 0\n \n 0\n
\n \\(391\\)\n \n 0\n \n 0\n
\n \\(392\\)\n \n 0\n \n 0\n
\n \\(393\\)\n \n 0\n \n 0\n
\n \\(394\\)\n \n \u22121.36603\n \n \u2212\n \n 0.366025i\n \u22121.36603\n \n \u2212\n \n 0.366025i
\n \\(395\\)\n \n 0\n \n 0\n
\n \\(396\\)\n \n 0\n \n 0\n
\n \\(397\\)\n \n 0.366025\n \n \u2212\n \n 1.36603i\n 0.366025\n \n \u2212\n \n 1.36603i\n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \\(398\\)\n \n 0\n \n 0\n
\n \\(399\\)\n \n 0\n \n 0\n
\n \\(400\\)\n \n \u2212\n \n 1.00000i\n \u2212\n \n 1.00000i
\n \\(401\\)\n \n 0.366025\n \n \u2212\n \n 1.36603i\n 0.366025\n \n \u2212\n \n 1.36603i\n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \\(402\\)\n \n 0\n \n 0\n
\n \\(403\\)\n \n 0\n \n 0\n
\n \\(404\\)\n \n 0\n \n 0\n
\n \\(405\\)\n \n \u22121.00000\n \n +\n \n 1.00000i\n \u22121.00000\n \n +\n \n 1.00000i
\n \\(406\\)\n \n 0\n \n 0\n
\n \\(407\\)\n \n 0\n \n 0\n
\n \\(408\\)\n \n 0\n \n 0\n
\n \\(409\\)\n \n \u22121.00000\n \n +\n \n 1.73205i\n \u22121.00000\n \n +\n \n 1.73205i\n \u22120.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \u22120.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(410\\)\n \n \u22121.73205\n \n \u2212\n \n 1.00000i\n \u22121.73205\n \n \u2212\n \n 1.00000i
\n \\(411\\)\n \n 0\n \n 0\n
\n \\(412\\)\n \n 0\n \n 0\n
\n \\(413\\)\n \n 0\n \n 0\n
\n \\(414\\)\n \n 0\n \n 0\n
\n \\(415\\)\n \n 0\n \n 0\n
\n \\(416\\)\n \n 0\n \n 0\n
\n \\(417\\)\n \n 0\n \n 0\n
\n \\(418\\)\n \n 0\n \n 0\n
\n \\(419\\)\n \n 0\n \n 0\n \n \u22120.707107\n \n \u2212\n \n 0.707107i\n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \\(0.250000\\pi\\)\n
\n \\(420\\)\n \n 0\n \n 0\n
\n \\(421\\)\n \n 0\n \n 0\n \n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(422\\)\n \n 0\n \n 0\n
\n \\(423\\)\n \n 0\n \n 0\n
\n \\(424\\)\n \n 0\n \n 0\n
\n \\(425\\)\n \n \u22120.866025\n \n +\n \n 0.500000i\n \u22120.866025\n \n +\n \n 0.500000i
\n \\(426\\)\n \n 0\n \n 0\n
\n \\(427\\)\n \n 0\n \n 0\n
\n \\(428\\)\n \n 0\n \n 0\n
\n \\(429\\)\n \n 0\n \n 0\n
\n \\(430\\)\n \n 0\n \n 0\n
\n \\(431\\)\n \n 0\n \n 0\n \n 0.965926\n \n \u2212\n \n 0.258819i\n \\(-0.0833333\\pi\\)\n
\n \u22120.965926\n \n +\n \n 0.258819i\n \\(0.916667\\pi\\)\n
\n \\(432\\)\n \n 0\n \n 0\n
\n \\(433\\)\n \n 2.00000i\n 2.00000i\n 1.00000i\n \\(0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(434\\)\n \n 0\n \n 0\n
\n \\(435\\)\n \n 0\n \n 0\n
\n \\(436\\)\n \n 0.366025\n \n \u2212\n \n 1.36603i\n 0.366025\n \n \u2212\n \n 1.36603i
\n \\(437\\)\n \n 0\n \n 0\n
\n \\(438\\)\n \n 0\n \n 0\n
\n \\(439\\)\n \n 0\n \n 0\n \n \u22120.965926\n \n \u2212\n \n 0.258819i\n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \\(0.0833333\\pi\\)\n
\n \\(440\\)\n \n 0\n \n 0\n
\n \\(441\\)\n \n 0\n \n 0\n
\n \\(442\\)\n \n 0\n \n 0\n
\n \\(443\\)\n \n 0\n \n 0\n \n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(444\\)\n \n 0\n \n 0\n
\n \\(445\\)\n \n 0\n \n 0\n
\n \\(446\\)\n \n 0\n \n 0\n
\n \\(447\\)\n \n 0\n \n 0\n
\n \\(448\\)\n \n 0\n \n 0\n
\n \\(449\\)\n \n \u22121.00000\n \n \u2212\n \n 1.00000i\n \u22121.00000\n \n \u2212\n \n 1.00000i\n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(450\\)\n \n 0.866025\n \n \u2212\n \n 0.500000i\n 0.866025\n \n \u2212\n \n 0.500000i
\n \\(451\\)\n \n 0\n \n 0\n
\n \\(452\\)\n \n \u22121.36603\n \n +\n \n 0.366025i\n \u22121.36603\n \n +\n \n 0.366025i
\n \\(453\\)\n \n 0\n \n 0\n
\n \\(454\\)\n \n 0\n \n 0\n
\n \\(455\\)\n \n 0\n \n 0\n
\n \\(456\\)\n \n 0\n \n 0\n
\n \\(457\\)\n \n \u22121.73205\n \n +\n \n 1.00000i\n \u22121.73205\n \n +\n \n 1.00000i\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(458\\)\n \n 1.00000\n \n \u2212\n \n 1.73205i\n 1.00000\n \n \u2212\n \n 1.73205i
\n \\(459\\)\n \n 0\n \n 0\n
\n \\(460\\)\n \n 0\n \n 0\n
\n \\(461\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(462\\)\n \n 0\n \n 0\n
\n \\(463\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(464\\)\n \n \u22121.36603\n \n \u2212\n \n 0.366025i\n \u22121.36603\n \n \u2212\n \n 0.366025i
\n \\(465\\)\n \n 0\n \n 0\n
\n \\(466\\)\n \n \u22121.36603\n \n +\n \n 0.366025i\n \u22121.36603\n \n +\n \n 0.366025i
\n \\(467\\)\n \n 0\n \n 0\n \n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(468\\)\n \n 0\n \n 0\n
\n \\(469\\)\n \n 0\n \n 0\n
\n \\(470\\)\n \n 0\n \n 0\n
\n \\(471\\)\n \n 0\n \n 0\n
\n \\(472\\)\n \n 0\n \n 0\n
\n \\(473\\)\n \n 0\n \n 0\n
\n \\(474\\)\n \n 0\n \n 0\n
\n \\(475\\)\n \n 0\n \n 0\n
\n \\(476\\)\n \n 0\n \n 0\n
\n \\(477\\)\n \n 0\n \n 0\n
\n \\(478\\)\n \n 0\n \n 0\n
\n \\(479\\)\n \n 0\n \n 0\n \n \u22120.258819\n \n \u2212\n \n 0.965926i\n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \\(0.416667\\pi\\)\n
\n \\(480\\)\n \n 0\n \n 0\n
\n \\(481\\)\n \n 0\n \n 0\n
\n \\(482\\)\n \n 1.00000\n \n +\n \n 1.00000i\n 1.00000\n \n +\n \n 1.00000i
\n \\(483\\)\n \n 0\n \n 0\n
\n \\(484\\)\n \n \u2212\n \n 1.00000i\n \u2212\n \n 1.00000i
\n \\(485\\)\n \n \u22121.73205\n \n +\n \n 1.00000i\n \u22121.73205\n \n +\n \n 1.00000i
\n \\(486\\)\n \n 0\n \n 0\n
\n \\(487\\)\n \n 0\n \n 0\n \n 0.965926\n \n \u2212\n \n 0.258819i\n \\(-0.0833333\\pi\\)\n
\n \u22120.965926\n \n +\n \n 0.258819i\n \\(0.916667\\pi\\)\n
\n \\(488\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i
\n \\(489\\)\n \n 0\n \n 0\n
\n \\(490\\)\n \n 0\n \n 0\n
\n \\(491\\)\n \n 0\n \n 0\n \n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(492\\)\n \n 0\n \n 0\n
\n \\(493\\)\n \n 0.366025\n \n +\n \n 1.36603i\n 0.366025\n \n +\n \n 1.36603i
\n \\(494\\)\n \n 0\n \n 0\n
\n \\(495\\)\n \n 0\n \n 0\n
\n \\(496\\)\n \n 0\n \n 0\n
\n \\(497\\)\n \n 0\n \n 0\n
\n \\(498\\)\n \n 0\n \n 0\n
\n \\(499\\)\n \n 0\n \n 0\n \n 0.258819\n \n \u2212\n \n 0.965926i\n \\(-0.416667\\pi\\)\n
\n \u22120.258819\n \n +\n \n 0.965926i\n \\(0.583333\\pi\\)\n
\n \\(500\\)\n \n 0\n \n 0\n
\n \\(501\\)\n \n 0\n \n 0\n
\n \\(502\\)\n \n 0\n \n 0\n
\n \\(503\\)\n \n 0\n \n 0\n \n \u22120.707107\n \n \u2212\n \n 0.707107i\n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \\(0.250000\\pi\\)\n
\n \\(504\\)\n \n 0\n \n 0\n
\n \\(505\\)\n \n 0\n \n 0\n
\n \\(506\\)\n \n 0\n \n 0\n
\n \\(507\\)\n \n 0\n \n 0\n
\n \\(508\\)\n \n 0\n \n 0\n
\n \\(509\\)\n \n \u22121.00000\n \n \u2212\n \n 1.73205i\n \u22121.00000\n \n \u2212\n \n 1.73205i\n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n \\(510\\)\n \n 0\n \n 0\n
\n \\(511\\)\n \n 0\n \n 0\n
\n \\(512\\)\n \n \u2212\n \n 1.00000i\n \u2212\n \n 1.00000i
\n \\(513\\)\n \n 0\n \n 0\n
\n \\(514\\)\n \n \u22121.00000\n \n +\n \n 1.73205i\n \u22121.00000\n \n +\n \n 1.73205i
\n \\(515\\)\n \n 0\n \n 0\n
\n \\(516\\)\n \n 0\n \n 0\n
\n \\(517\\)\n \n 0\n \n 0\n
\n \\(518\\)\n \n 0\n \n 0\n
\n \\(519\\)\n \n 0\n \n 0\n
\n \\(520\\)\n \n 0\n \n 0\n
\n \\(521\\)\n \n 1.36603\n \n \u2212\n \n 0.366025i\n 1.36603\n \n \u2212\n \n 0.366025i\n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(522\\)\n \n \u22120.366025\n \n \u2212\n \n 1.36603i\n \u22120.366025\n \n \u2212\n \n 1.36603i
\n \\(523\\)\n \n 0\n \n 0\n \n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(524\\)\n \n 0\n \n 0\n
\n \\(525\\)\n \n 0\n \n 0\n
\n \\(526\\)\n \n 0\n \n 0\n
\n \\(527\\)\n \n 0\n \n 0\n
\n \\(528\\)\n \n 0\n \n 0\n
\n \\(529\\)\n \n \u22120.866025\n \n \u2212\n \n 0.500000i\n \u22120.866025\n \n \u2212\n \n 0.500000i
\n \\(530\\)\n \n 0\n \n 0\n
\n \\(531\\)\n \n 0\n \n 0\n
\n \\(532\\)\n \n 0\n \n 0\n
\n \\(533\\)\n \n 0\n \n 0\n
\n \\(534\\)\n \n 0\n \n 0\n
\n \\(535\\)\n \n 0\n \n 0\n
\n \\(536\\)\n \n 0\n \n 0\n
\n \\(537\\)\n \n 0\n \n 0\n
\n \\(538\\)\n \n \u22121.00000\n \n \u2212\n \n 1.00000i\n \u22121.00000\n \n \u2212\n \n 1.00000i
\n \\(539\\)\n \n 0\n \n 0\n
\n \\(540\\)\n \n 0\n \n 0\n
\n \\(541\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i\n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(542\\)\n \n 0\n \n 0\n
\n \\(543\\)\n \n 0\n \n 0\n
\n \\(544\\)\n \n \u22120.866025\n \n +\n \n 0.500000i\n \u22120.866025\n \n +\n \n 0.500000i
\n \\(545\\)\n \n \u22122.00000\n \n \u22122.00000\n
\n \\(546\\)\n \n 0\n \n 0\n
\n \\(547\\)\n \n 0\n \n 0\n \n 0.707107\n \n \u2212\n \n 0.707107i\n \\(-0.250000\\pi\\)\n
\n \u22120.707107\n \n +\n \n 0.707107i\n \\(0.750000\\pi\\)\n
\n \\(548\\)\n \n 0\n \n 0\n
\n \\(549\\)\n \n 0.366025\n \n +\n \n 1.36603i\n 0.366025\n \n +\n \n 1.36603i
\n \\(550\\)\n \n 0\n \n 0\n
\n \\(551\\)\n \n 0\n \n 0\n
\n \\(552\\)\n \n 0\n \n 0\n
\n \\(553\\)\n \n 0\n \n 0\n
\n \\(554\\)\n \n \u22121.00000\n \n \u2212\n \n 1.00000i\n \u22121.00000\n \n \u2212\n \n 1.00000i
\n \\(555\\)\n \n 0\n \n 0\n
\n \\(556\\)\n \n 0\n \n 0\n
\n \\(557\\)\n \n 0\n \n 0\n \n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(558\\)\n \n 0\n \n 0\n
\n \\(559\\)\n \n 0\n \n 0\n
\n \\(560\\)\n \n 0\n \n 0\n
\n \\(561\\)\n \n 0\n \n 0\n
\n \\(562\\)\n \n 0\n \n 0\n
\n \\(563\\)\n \n 0\n \n 0\n \n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(564\\)\n \n 0\n \n 0\n
\n \\(565\\)\n \n 1.00000\n \n +\n \n 1.73205i\n 1.00000\n \n +\n \n 1.73205i
\n \\(566\\)\n \n 0\n \n 0\n
\n \\(567\\)\n \n 0\n \n 0\n
\n \\(568\\)\n \n 0\n \n 0\n
\n \\(569\\)\n \n 0\n \n 0\n \n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(570\\)\n \n 0\n \n 0\n
\n \\(571\\)\n \n 0\n \n 0\n \n 0.965926\n \n \u2212\n \n 0.258819i\n \\(-0.0833333\\pi\\)\n
\n \u22120.965926\n \n +\n \n 0.258819i\n \\(0.916667\\pi\\)\n
\n \\(572\\)\n \n 0\n \n 0\n
\n \\(573\\)\n \n 0\n \n 0\n
\n \\(574\\)\n \n 0\n \n 0\n
\n \\(575\\)\n \n 0\n \n 0\n
\n \\(576\\)\n \n 0.866025\n \n \u2212\n \n 0.500000i\n 0.866025\n \n \u2212\n \n 0.500000i
\n \\(577\\)\n \n 0\n \n 0\n \n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(578\\)\n \n 0.866025\n \n +\n \n 0.500000i\n 0.866025\n \n +\n \n 0.500000i
\n \\(579\\)\n \n 0\n \n 0\n
\n \\(580\\)\n \n 2.00000i\n 2.00000i
\n \\(581\\)\n \n 0\n \n 0\n
\n \\(582\\)\n \n 0\n \n 0\n
\n \\(583\\)\n \n 0\n \n 0\n
\n \\(584\\)\n \n 1.36603\n \n \u2212\n \n 0.366025i\n 1.36603\n \n \u2212\n \n 0.366025i
\n \\(585\\)\n \n 0\n \n 0\n
\n \\(586\\)\n \n \u22121.73205\n \n +\n \n 1.00000i\n \u22121.73205\n \n +\n \n 1.00000i
\n \\(587\\)\n \n 0\n \n 0\n \n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(588\\)\n \n 0\n \n 0\n
\n \\(589\\)\n \n 0\n \n 0\n
\n \\(590\\)\n \n 0\n \n 0\n
\n \\(591\\)\n \n 0\n \n 0\n
\n \\(592\\)\n \n \u22120.366025\n \n \u2212\n \n 1.36603i\n \u22120.366025\n \n \u2212\n \n 1.36603i
\n \\(593\\)\n \n 0\n \n 0\n \n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(594\\)\n \n 0\n \n 0\n
\n \\(595\\)\n \n 0\n \n 0\n
\n \\(596\\)\n \n \u22122.00000\n \n \u22122.00000\n
\n \\(597\\)\n \n 0\n \n 0\n
\n \\(598\\)\n \n 0\n \n 0\n
\n \\(599\\)\n \n 0\n \n 0\n \n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n \u22120.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(600\\)\n \n 0\n \n 0\n
\n \\(601\\)\n \n \u22121.00000\n \n \u2212\n \n 1.00000i\n \u22121.00000\n \n \u2212\n \n 1.00000i\n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(602\\)\n \n 0\n \n 0\n
\n \\(603\\)\n \n 0\n \n 0\n
\n \\(604\\)\n \n 0\n \n 0\n
\n \\(605\\)\n \n \u22121.36603\n \n +\n \n 0.366025i\n \u22121.36603\n \n +\n \n 0.366025i
\n \\(606\\)\n \n 0\n \n 0\n
\n \\(607\\)\n \n 0\n \n 0\n \n \u22120.965926\n \n \u2212\n \n 0.258819i\n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \\(0.0833333\\pi\\)\n
\n \\(608\\)\n \n 0\n \n 0\n
\n \\(609\\)\n \n 0\n \n 0\n
\n \\(610\\)\n \n \u2212\n \n 2.00000i\n \u2212\n \n 2.00000i
\n \\(611\\)\n \n 0\n \n 0\n
\n \\(612\\)\n \n \u22120.866025\n \n \u2212\n \n 0.500000i\n \u22120.866025\n \n \u2212\n \n 0.500000i
\n \\(613\\)\n \n \u22121.00000\n \n +\n \n 1.73205i\n \u22121.00000\n \n +\n \n 1.73205i\n \u22120.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \u22120.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(614\\)\n \n 0\n \n 0\n
\n \\(615\\)\n \n 0\n \n 0\n
\n \\(616\\)\n \n 0\n \n 0\n
\n \\(617\\)\n \n \u22121.00000\n \n +\n \n 1.00000i\n \u22121.00000\n \n +\n \n 1.00000i\n 1.00000i\n \\(0.5\\pi\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(618\\)\n \n 0\n \n 0\n
\n \\(619\\)\n \n 0\n \n 0\n \n 0.965926\n \n \u2212\n \n 0.258819i\n \\(-0.0833333\\pi\\)\n
\n \u22120.965926\n \n +\n \n 0.258819i\n \\(0.916667\\pi\\)\n
\n \\(620\\)\n \n 0\n \n 0\n
\n \\(621\\)\n \n 0\n \n 0\n
\n \\(622\\)\n \n 0\n \n 0\n
\n \\(623\\)\n \n 0\n \n 0\n
\n \\(624\\)\n \n 0\n \n 0\n
\n \\(625\\)\n \n \u22120.500000\n \n \u2212\n \n 0.866025i\n \u22120.500000\n \n \u2212\n \n 0.866025i
\n \\(626\\)\n \n \u22120.366025\n \n \u2212\n \n 1.36603i\n \u22120.366025\n \n \u2212\n \n 1.36603i
\n \\(627\\)\n \n 0\n \n 0\n
\n \\(628\\)\n \n \u22121.00000\n \n \u2212\n \n 1.73205i\n \u22121.00000\n \n \u2212\n \n 1.73205i
\n \\(629\\)\n \n \u22121.00000\n \n +\n \n 1.00000i\n \u22121.00000\n \n +\n \n 1.00000i
\n \\(630\\)\n \n 0\n \n 0\n
\n \\(631\\)\n \n 0\n \n 0\n \n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(632\\)\n \n 0\n \n 0\n
\n \\(633\\)\n \n 0\n \n 0\n
\n \\(634\\)\n \n 0.366025\n \n +\n \n 1.36603i\n 0.366025\n \n +\n \n 1.36603i
\n \\(635\\)\n \n 0\n \n 0\n
\n \\(636\\)\n \n 0\n \n 0\n
\n \\(637\\)\n \n 0\n \n 0\n
\n \\(638\\)\n \n 0\n \n 0\n
\n \\(639\\)\n \n 0\n \n 0\n
\n \\(640\\)\n \n \u22121.36603\n \n +\n \n 0.366025i\n \u22121.36603\n \n +\n \n 0.366025i
\n \\(641\\)\n \n \u22120.366025\n \n \u2212\n \n 1.36603i\n \u22120.366025\n \n \u2212\n \n 1.36603i\n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n \\(642\\)\n \n 0\n \n 0\n
\n \\(643\\)\n \n 0\n \n 0\n \n 0.707107\n \n \u2212\n \n 0.707107i\n \\(-0.250000\\pi\\)\n
\n \u22120.707107\n \n +\n \n 0.707107i\n \\(0.750000\\pi\\)\n
\n \\(644\\)\n \n 0\n \n 0\n
\n \\(645\\)\n \n 0\n \n 0\n
\n \\(646\\)\n \n 0\n \n 0\n
\n \\(647\\)\n \n 0\n \n 0\n \n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n \u22120.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(648\\)\n \n 0.866025\n \n +\n \n 0.500000i\n 0.866025\n \n +\n \n 0.500000i
\n \\(649\\)\n \n 0\n \n 0\n
\n \\(650\\)\n \n 0\n \n 0\n
\n \\(651\\)\n \n 0\n \n 0\n
\n \\(652\\)\n \n 0\n \n 0\n
\n \\(653\\)\n \n 0.366025\n \n \u2212\n \n 1.36603i\n 0.366025\n \n \u2212\n \n 1.36603i\n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \\(654\\)\n \n 0\n \n 0\n
\n \\(655\\)\n \n 0\n \n 0\n
\n \\(656\\)\n \n \u22120.366025\n \n +\n \n 1.36603i\n \u22120.366025\n \n +\n \n 1.36603i
\n \\(657\\)\n \n 1.00000\n \n +\n \n 1.00000i\n 1.00000\n \n +\n \n 1.00000i
\n \\(658\\)\n \n 0\n \n 0\n
\n \\(659\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(660\\)\n \n 0\n \n 0\n
\n \\(661\\)\n \n 0\n \n 0\n \n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n \u22120.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(662\\)\n \n 0\n \n 0\n
\n \\(663\\)\n \n 0\n \n 0\n
\n \\(664\\)\n \n 0\n \n 0\n
\n \\(665\\)\n \n 0\n \n 0\n
\n \\(666\\)\n \n 1.00000\n \n \u2212\n \n 1.00000i\n 1.00000\n \n \u2212\n \n 1.00000i
\n \\(667\\)\n \n 0\n \n 0\n
\n \\(668\\)\n \n 0\n \n 0\n
\n \\(669\\)\n \n 0\n \n 0\n
\n \\(670\\)\n \n 0\n \n 0\n
\n \\(671\\)\n \n 0\n \n 0\n
\n \\(672\\)\n \n 0\n \n 0\n
\n \\(673\\)\n \n \u22121.00000\n \n \u2212\n \n 1.00000i\n \u22121.00000\n \n \u2212\n \n 1.00000i\n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(674\\)\n \n \u22120.366025\n \n +\n \n 1.36603i\n \u22120.366025\n \n +\n \n 1.36603i
\n \\(675\\)\n \n 0\n \n 0\n
\n \\(676\\)\n \n \u22120.500000\n \n +\n \n 0.866025i\n \u22120.500000\n \n +\n \n 0.866025i
\n \\(677\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i\n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(678\\)\n \n 0\n \n 0\n
\n \\(679\\)\n \n 0\n \n 0\n
\n \\(680\\)\n \n 1.00000\n \n +\n \n 1.00000i\n 1.00000\n \n +\n \n 1.00000i
\n \\(681\\)\n \n 0\n \n 0\n
\n \\(682\\)\n \n 0\n \n 0\n
\n \\(683\\)\n \n 0\n \n 0\n \n \u22120.258819\n \n \u2212\n \n 0.965926i\n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \\(0.416667\\pi\\)\n
\n \\(684\\)\n \n 0\n \n 0\n
\n \\(685\\)\n \n 0\n \n 0\n
\n \\(686\\)\n \n 0\n \n 0\n
\n \\(687\\)\n \n 0\n \n 0\n
\n \\(688\\)\n \n 0\n \n 0\n
\n \\(689\\)\n \n 0\n \n 0\n
\n \\(690\\)\n \n 0\n \n 0\n
\n \\(691\\)\n \n 0\n \n 0\n \n 0.258819\n \n \u2212\n \n 0.965926i\n \\(-0.416667\\pi\\)\n
\n \u22120.258819\n \n +\n \n 0.965926i\n \\(0.583333\\pi\\)\n
\n \\(692\\)\n \n 1.00000\n \n \u2212\n \n 1.00000i\n 1.00000\n \n \u2212\n \n 1.00000i
\n \\(693\\)\n \n 0\n \n 0\n
\n \\(694\\)\n \n 0\n \n 0\n
\n \\(695\\)\n \n 0\n \n 0\n
\n \\(696\\)\n \n 0\n \n 0\n
\n \\(697\\)\n \n 1.36603\n \n \u2212\n \n 0.366025i\n 1.36603\n \n \u2212\n \n 0.366025i
\n \\(698\\)\n \n 0\n \n 0\n
\n \\(699\\)\n \n 0\n \n 0\n
\n \\(700\\)\n \n 0\n \n 0\n
\n \\(701\\)\n \n 0\n \n 0\n \n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(702\\)\n \n 0\n \n 0\n
\n \\(703\\)\n \n 0\n \n 0\n
\n \\(704\\)\n \n 0\n \n 0\n
\n \\(705\\)\n \n 0\n \n 0\n
\n \\(706\\)\n \n \u2212\n \n 2.00000i\n \u2212\n \n 2.00000i
\n \\(707\\)\n \n 0\n \n 0\n
\n \\(708\\)\n \n 0\n \n 0\n
\n \\(709\\)\n \n \u22121.36603\n \n \u2212\n \n 0.366025i\n \u22121.36603\n \n \u2212\n \n 0.366025i\n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(710\\)\n \n 0\n \n 0\n
\n \\(711\\)\n \n 0\n \n 0\n
\n \\(712\\)\n \n 0\n \n 0\n
\n \\(713\\)\n \n 0\n \n 0\n
\n \\(714\\)\n \n 0\n \n 0\n
\n \\(715\\)\n \n 0\n \n 0\n
\n \\(716\\)\n \n 0\n \n 0\n
\n \\(717\\)\n \n 0\n \n 0\n
\n \\(718\\)\n \n 0\n \n 0\n
\n \\(719\\)\n \n 0\n \n 0\n \n \u22120.965926\n \n \u2212\n \n 0.258819i\n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \\(0.0833333\\pi\\)\n
\n \\(720\\)\n \n \u22121.00000\n \n \u2212\n \n 1.00000i\n \u22121.00000\n \n \u2212\n \n 1.00000i
\n \\(721\\)\n \n 0\n \n 0\n
\n \\(722\\)\n \n 1.00000i\n 1.00000i
\n \\(723\\)\n \n 0\n \n 0\n
\n \\(724\\)\n \n 1.36603\n \n \u2212\n \n 0.366025i\n 1.36603\n \n \u2212\n \n 0.366025i
\n \\(725\\)\n \n 1.36603\n \n \u2212\n \n 0.366025i\n 1.36603\n \n \u2212\n \n 0.366025i
\n \\(726\\)\n \n 0\n \n 0\n
\n \\(727\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(728\\)\n \n 0\n \n 0\n
\n \\(729\\)\n \n 1.00000i\n 1.00000i
\n \\(730\\)\n \n \u22121.00000\n \n \u2212\n \n 1.73205i\n \u22121.00000\n \n \u2212\n \n 1.73205i
\n \\(731\\)\n \n 0\n \n 0\n
\n \\(732\\)\n \n 0\n \n 0\n
\n \\(733\\)\n \n 0\n \n 0\n \n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(734\\)\n \n 0\n \n 0\n
\n \\(735\\)\n \n 0\n \n 0\n
\n \\(736\\)\n \n 0\n \n 0\n
\n \\(737\\)\n \n 0\n \n 0\n
\n \\(738\\)\n \n \u22121.36603\n \n +\n \n 0.366025i\n \u22121.36603\n \n +\n \n 0.366025i
\n \\(739\\)\n \n 0\n \n 0\n \n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(740\\)\n \n \u22121.73205\n \n +\n \n 1.00000i\n \u22121.73205\n \n +\n \n 1.00000i
\n \\(741\\)\n \n 0\n \n 0\n
\n \\(742\\)\n \n 0\n \n 0\n
\n \\(743\\)\n \n 0\n \n 0\n \n 0.707107\n \n \u2212\n \n 0.707107i\n \\(-0.250000\\pi\\)\n
\n \u22120.707107\n \n +\n \n 0.707107i\n \\(0.750000\\pi\\)\n
\n \\(744\\)\n \n 0\n \n 0\n
\n \\(745\\)\n \n 0.732051\n \n +\n \n 2.73205i\n 0.732051\n \n +\n \n 2.73205i
\n \\(746\\)\n \n 0\n \n 0\n
\n \\(747\\)\n \n 0\n \n 0\n
\n \\(748\\)\n \n 0\n \n 0\n
\n \\(749\\)\n \n 0\n \n 0\n
\n \\(750\\)\n \n 0\n \n 0\n
\n \\(751\\)\n \n 0\n \n 0\n \n \u22120.965926\n \n \u2212\n \n 0.258819i\n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \\(0.0833333\\pi\\)\n
\n \\(752\\)\n \n 0\n \n 0\n
\n \\(753\\)\n \n 0\n \n 0\n
\n \\(754\\)\n \n 0\n \n 0\n
\n \\(755\\)\n \n 0\n \n 0\n
\n \\(756\\)\n \n 0\n \n 0\n
\n \\(757\\)\n \n 2.00000i\n 2.00000i\n 1.00000i\n \\(0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(758\\)\n \n 0\n \n 0\n
\n \\(759\\)\n \n 0\n \n 0\n
\n \\(760\\)\n \n 0\n \n 0\n
\n \\(761\\)\n \n 0\n \n 0\n \n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(762\\)\n \n 0\n \n 0\n
\n \\(763\\)\n \n 0\n \n 0\n
\n \\(764\\)\n \n 0\n \n 0\n
\n \\(765\\)\n \n \u22120.366025\n \n +\n \n 1.36603i\n \u22120.366025\n \n +\n \n 1.36603i
\n \\(766\\)\n \n 0\n \n 0\n
\n \\(767\\)\n \n 0\n \n 0\n
\n \\(768\\)\n \n 0\n \n 0\n
\n \\(769\\)\n \n 0\n \n 0\n \n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(770\\)\n \n 0\n \n 0\n
\n \\(771\\)\n \n 0\n \n 0\n
\n \\(772\\)\n \n \u22120.366025\n \n +\n \n 1.36603i\n \u22120.366025\n \n +\n \n 1.36603i
\n \\(773\\)\n \n \u22121.73205\n \n \u2212\n \n 1.00000i\n \u22121.73205\n \n \u2212\n \n 1.00000i\n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n \\(774\\)\n \n 0\n \n 0\n
\n \\(775\\)\n \n 0\n \n 0\n
\n \\(776\\)\n \n 1.00000\n \n +\n \n 1.00000i\n 1.00000\n \n +\n \n 1.00000i
\n \\(777\\)\n \n 0\n \n 0\n
\n \\(778\\)\n \n 2.00000\n \n 2.00000\n
\n \\(779\\)\n \n 0\n \n 0\n
\n \\(780\\)\n \n 0\n \n 0\n
\n \\(781\\)\n \n 0\n \n 0\n
\n \\(782\\)\n \n 0\n \n 0\n
\n \\(783\\)\n \n 0\n \n 0\n
\n \\(784\\)\n \n 0\n \n 0\n
\n \\(785\\)\n \n \u22122.00000\n \n +\n \n 2.00000i\n \u22122.00000\n \n +\n \n 2.00000i
\n \\(786\\)\n \n 0\n \n 0\n
\n \\(787\\)\n \n 0\n \n 0\n \n \u22120.258819\n \n \u2212\n \n 0.965926i\n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \\(0.416667\\pi\\)\n
\n \\(788\\)\n \n 1.36603\n \n \u2212\n \n 0.366025i\n 1.36603\n \n \u2212\n \n 0.366025i
\n \\(789\\)\n \n 0\n \n 0\n
\n \\(790\\)\n \n 0\n \n 0\n
\n \\(791\\)\n \n 0\n \n 0\n
\n \\(792\\)\n \n 0\n \n 0\n
\n \\(793\\)\n \n 0\n \n 0\n
\n \\(794\\)\n \n 0.366025\n \n +\n \n 1.36603i\n 0.366025\n \n +\n \n 1.36603i
\n \\(795\\)\n \n 0\n \n 0\n
\n \\(796\\)\n \n 0\n \n 0\n
\n \\(797\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(798\\)\n \n 0\n \n 0\n
\n \\(799\\)\n \n 0\n \n 0\n
\n \\(800\\)\n \n 0.500000\n \n +\n \n 0.866025i\n 0.500000\n \n +\n \n 0.866025i
\n \\(801\\)\n \n 0\n \n 0\n
\n \\(802\\)\n \n 0.366025\n \n +\n \n 1.36603i\n 0.366025\n \n +\n \n 1.36603i
\n \\(803\\)\n \n 0\n \n 0\n
\n \\(804\\)\n \n 0\n \n 0\n
\n \\(805\\)\n \n 0\n \n 0\n
\n \\(806\\)\n \n 0\n \n 0\n
\n \\(807\\)\n \n 0\n \n 0\n
\n \\(808\\)\n \n 0\n \n 0\n
\n \\(809\\)\n \n 1.36603\n \n \u2212\n \n 0.366025i\n 1.36603\n \n \u2212\n \n 0.366025i\n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(810\\)\n \n 0.366025\n \n \u2212\n \n 1.36603i\n 0.366025\n \n \u2212\n \n 1.36603i
\n \\(811\\)\n \n 0\n \n 0\n \n 0.707107\n \n \u2212\n \n 0.707107i\n \\(-0.250000\\pi\\)\n
\n \u22120.707107\n \n +\n \n 0.707107i\n \\(0.750000\\pi\\)\n
\n \\(812\\)\n \n 0\n \n 0\n
\n \\(813\\)\n \n 0\n \n 0\n
\n \\(814\\)\n \n 0\n \n 0\n
\n \\(815\\)\n \n 0\n \n 0\n
\n \\(816\\)\n \n 0\n \n 0\n
\n \\(817\\)\n \n 0\n \n 0\n
\n \\(818\\)\n \n \u2212\n \n 2.00000i\n \u2212\n \n 2.00000i
\n \\(819\\)\n \n 0\n \n 0\n
\n \\(820\\)\n \n 2.00000\n \n 2.00000\n
\n \\(821\\)\n \n \u22121.36603\n \n \u2212\n \n 0.366025i\n \u22121.36603\n \n \u2212\n \n 0.366025i\n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(822\\)\n \n 0\n \n 0\n
\n \\(823\\)\n \n 0\n \n 0\n \n 0.965926\n \n \u2212\n \n 0.258819i\n \\(-0.0833333\\pi\\)\n
\n \u22120.965926\n \n +\n \n 0.258819i\n \\(0.916667\\pi\\)\n
\n \\(824\\)\n \n 0\n \n 0\n
\n \\(825\\)\n \n 0\n \n 0\n
\n \\(826\\)\n \n 0\n \n 0\n
\n \\(827\\)\n \n 0\n \n 0\n \n \u22120.707107\n \n \u2212\n \n 0.707107i\n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \\(0.250000\\pi\\)\n
\n \\(828\\)\n \n 0\n \n 0\n
\n \\(829\\)\n \n 1.00000\n \n \u2212\n \n 1.73205i\n 1.00000\n \n \u2212\n \n 1.73205i\n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n \\(830\\)\n \n 0\n \n 0\n
\n \\(831\\)\n \n 0\n \n 0\n
\n \\(832\\)\n \n 0\n \n 0\n
\n \\(833\\)\n \n 0\n \n 0\n
\n \\(834\\)\n \n 0\n \n 0\n
\n \\(835\\)\n \n 0\n \n 0\n
\n \\(836\\)\n \n 0\n \n 0\n
\n \\(837\\)\n \n 0\n \n 0\n
\n \\(838\\)\n \n 0\n \n 0\n
\n \\(839\\)\n \n 0\n \n 0\n \n \u22120.707107\n \n \u2212\n \n 0.707107i\n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \\(0.250000\\pi\\)\n
\n \\(840\\)\n \n 0\n \n 0\n
\n \\(841\\)\n \n \u2212\n \n 1.00000i\n \u2212\n \n 1.00000i
\n \\(842\\)\n \n 0\n \n 0\n
\n \\(843\\)\n \n 0\n \n 0\n
\n \\(844\\)\n \n 0\n \n 0\n
\n \\(845\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i
\n \\(846\\)\n \n 0\n \n 0\n
\n \\(847\\)\n \n 0\n \n 0\n
\n \\(848\\)\n \n 0\n \n 0\n
\n \\(849\\)\n \n 0\n \n 0\n
\n \\(850\\)\n \n 0.500000\n \n \u2212\n \n 0.866025i\n 0.500000\n \n \u2212\n \n 0.866025i
\n \\(851\\)\n \n 0\n \n 0\n
\n \\(852\\)\n \n 0\n \n 0\n
\n \\(853\\)\n \n 1.00000\n \n \u2212\n \n 1.00000i\n 1.00000\n \n \u2212\n \n 1.00000i\n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000\n \n \\(0\\)\n
\n \\(854\\)\n \n 0\n \n 0\n
\n \\(855\\)\n \n 0\n \n 0\n
\n \\(856\\)\n \n 0\n \n 0\n
\n \\(857\\)\n \n 1.36603\n \n \u2212\n \n 0.366025i\n 1.36603\n \n \u2212\n \n 0.366025i\n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(858\\)\n \n 0\n \n 0\n
\n \\(859\\)\n \n 0\n \n 0\n \n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(860\\)\n \n 0\n \n 0\n
\n \\(861\\)\n \n 0\n \n 0\n
\n \\(862\\)\n \n 0\n \n 0\n
\n \\(863\\)\n \n 0\n \n 0\n \n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(864\\)\n \n 0\n \n 0\n
\n \\(865\\)\n \n \u22121.73205\n \n \u2212\n \n 1.00000i\n \u22121.73205\n \n \u2212\n \n 1.00000i
\n \\(866\\)\n \n \u22121.00000\n \n \u2212\n \n 1.73205i\n \u22121.00000\n \n \u2212\n \n 1.73205i
\n \\(867\\)\n \n 0\n \n 0\n
\n \\(868\\)\n \n 0\n \n 0\n
\n \\(869\\)\n \n 0\n \n 0\n
\n \\(870\\)\n \n 0\n \n 0\n
\n \\(871\\)\n \n 0\n \n 0\n
\n \\(872\\)\n \n 0.366025\n \n +\n \n 1.36603i\n 0.366025\n \n +\n \n 1.36603i
\n \\(873\\)\n \n \u22120.366025\n \n +\n \n 1.36603i\n \u22120.366025\n \n +\n \n 1.36603i
\n \\(874\\)\n \n 0\n \n 0\n
\n \\(875\\)\n \n 0\n \n 0\n
\n \\(876\\)\n \n 0\n \n 0\n
\n \\(877\\)\n \n \u22120.366025\n \n +\n \n 1.36603i\n \u22120.366025\n \n +\n \n 1.36603i\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(878\\)\n \n 0\n \n 0\n
\n \\(879\\)\n \n 0\n \n 0\n
\n \\(880\\)\n \n 0\n \n 0\n
\n \\(881\\)\n \n \u22121.00000\n \n +\n \n 1.00000i\n \u22121.00000\n \n +\n \n 1.00000i\n 1.00000i\n \\(0.5\\pi\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(882\\)\n \n 0\n \n 0\n
\n \\(883\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(884\\)\n \n 0\n \n 0\n
\n \\(885\\)\n \n 0\n \n 0\n
\n \\(886\\)\n \n 0\n \n 0\n
\n \\(887\\)\n \n 0\n \n 0\n \n \u22120.965926\n \n \u2212\n \n 0.258819i\n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \\(0.0833333\\pi\\)\n
\n \\(888\\)\n \n 0\n \n 0\n
\n \\(889\\)\n \n 0\n \n 0\n
\n \\(890\\)\n \n 0\n \n 0\n
\n \\(891\\)\n \n 0\n \n 0\n
\n \\(892\\)\n \n 0\n \n 0\n
\n \\(893\\)\n \n 0\n \n 0\n
\n \\(894\\)\n \n 0\n \n 0\n
\n \\(895\\)\n \n 0\n \n 0\n
\n \\(896\\)\n \n 0\n \n 0\n
\n \\(897\\)\n \n 0\n \n 0\n
\n \\(898\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i
\n \\(899\\)\n \n 0\n \n 0\n
\n \\(900\\)\n \n \u22120.500000\n \n +\n \n 0.866025i\n \u22120.500000\n \n +\n \n 0.866025i
\n \\(901\\)\n \n 0\n \n 0\n
\n \\(902\\)\n \n 0\n \n 0\n
\n \\(903\\)\n \n 0\n \n 0\n
\n \\(904\\)\n \n 1.00000\n \n \u2212\n \n 1.00000i\n 1.00000\n \n \u2212\n \n 1.00000i
\n \\(905\\)\n \n \u22121.00000\n \n \u2212\n \n 1.73205i\n \u22121.00000\n \n \u2212\n \n 1.73205i
\n \\(906\\)\n \n 0\n \n 0\n
\n \\(907\\)\n \n 0\n \n 0\n \n 0.965926\n \n \u2212\n \n 0.258819i\n \\(-0.0833333\\pi\\)\n
\n \u22120.965926\n \n +\n \n 0.258819i\n \\(0.916667\\pi\\)\n
\n \\(908\\)\n \n 0\n \n 0\n
\n \\(909\\)\n \n 0\n \n 0\n
\n \\(910\\)\n \n 0\n \n 0\n
\n \\(911\\)\n \n 0\n \n 0\n \n \u22120.707107\n \n \u2212\n \n 0.707107i\n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \\(0.250000\\pi\\)\n
\n \\(912\\)\n \n 0\n \n 0\n
\n \\(913\\)\n \n 0\n \n 0\n
\n \\(914\\)\n \n 1.00000\n \n \u2212\n \n 1.73205i\n 1.00000\n \n \u2212\n \n 1.73205i
\n \\(915\\)\n \n 0\n \n 0\n
\n \\(916\\)\n \n 2.00000i\n 2.00000i
\n \\(917\\)\n \n 0\n \n 0\n
\n \\(918\\)\n \n 0\n \n 0\n
\n \\(919\\)\n \n 0\n \n 0\n \n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(920\\)\n \n 0\n \n 0\n
\n \\(921\\)\n \n 0\n \n 0\n
\n \\(922\\)\n \n 0\n \n 0\n
\n \\(923\\)\n \n 0\n \n 0\n
\n \\(924\\)\n \n 0\n \n 0\n
\n \\(925\\)\n \n 1.00000\n \n +\n \n 1.00000i\n 1.00000\n \n +\n \n 1.00000i
\n \\(926\\)\n \n 0\n \n 0\n
\n \\(927\\)\n \n 0\n \n 0\n
\n \\(928\\)\n \n 1.36603\n \n \u2212\n \n 0.366025i\n 1.36603\n \n \u2212\n \n 0.366025i
\n \\(929\\)\n \n \u22120.366025\n \n +\n \n 1.36603i\n \u22120.366025\n \n +\n \n 1.36603i\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(930\\)\n \n 0\n \n 0\n
\n \\(931\\)\n \n 0\n \n 0\n
\n \\(932\\)\n \n 1.00000\n \n \u2212\n \n 1.00000i\n 1.00000\n \n \u2212\n \n 1.00000i
\n \\(933\\)\n \n 0\n \n 0\n
\n \\(934\\)\n \n 0\n \n 0\n
\n \\(935\\)\n \n 0\n \n 0\n
\n \\(936\\)\n \n 0\n \n 0\n
\n \\(937\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(938\\)\n \n 0\n \n 0\n
\n \\(939\\)\n \n 0\n \n 0\n
\n \\(940\\)\n \n 0\n \n 0\n
\n \\(941\\)\n \n 1.36603\n \n \u2212\n \n 0.366025i\n 1.36603\n \n \u2212\n \n 0.366025i\n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(942\\)\n \n 0\n \n 0\n
\n \\(943\\)\n \n 0\n \n 0\n
\n \\(944\\)\n \n 0\n \n 0\n
\n \\(945\\)\n \n 0\n \n 0\n
\n \\(946\\)\n \n 0\n \n 0\n
\n \\(947\\)\n \n 0\n \n 0\n \n \u22120.965926\n \n \u2212\n \n 0.258819i\n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \\(0.0833333\\pi\\)\n
\n \\(948\\)\n \n 0\n \n 0\n
\n \\(949\\)\n \n 0\n \n 0\n
\n \\(950\\)\n \n 0\n \n 0\n
\n \\(951\\)\n \n 0\n \n 0\n
\n \\(952\\)\n \n 0\n \n 0\n
\n \\(953\\)\n \n 0\n \n 0\n \n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(954\\)\n \n 0\n \n 0\n
\n \\(955\\)\n \n 0\n \n 0\n
\n \\(956\\)\n \n 0\n \n 0\n
\n \\(957\\)\n \n 0\n \n 0\n
\n \\(958\\)\n \n 0\n \n 0\n
\n \\(959\\)\n \n 0\n \n 0\n
\n \\(960\\)\n \n 0\n \n 0\n
\n \\(961\\)\n \n \u22120.866025\n \n +\n \n 0.500000i\n \u22120.866025\n \n +\n \n 0.500000i
\n \\(962\\)\n \n 0\n \n 0\n
\n \\(963\\)\n \n 0\n \n 0\n
\n \\(964\\)\n \n \u22121.36603\n \n \u2212\n \n 0.366025i\n \u22121.36603\n \n \u2212\n \n 0.366025i
\n \\(965\\)\n \n 2.00000\n \n 2.00000\n
\n \\(966\\)\n \n 0\n \n 0\n
\n \\(967\\)\n \n 0\n \n 0\n \n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(968\\)\n \n 0.500000\n \n +\n \n 0.866025i\n 0.500000\n \n +\n \n 0.866025i
\n \\(969\\)\n \n 0\n \n 0\n
\n \\(970\\)\n \n 1.00000\n \n \u2212\n \n 1.73205i\n 1.00000\n \n \u2212\n \n 1.73205i
\n \\(971\\)\n \n 0\n \n 0\n \n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(972\\)\n \n 0\n \n 0\n
\n \\(973\\)\n \n 0\n \n 0\n
\n \\(974\\)\n \n 0\n \n 0\n
\n \\(975\\)\n \n 0\n \n 0\n
\n \\(976\\)\n \n \u22121.36603\n \n +\n \n 0.366025i\n \u22121.36603\n \n +\n \n 0.366025i
\n \\(977\\)\n \n 0\n \n 0\n \n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n \u22120.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(978\\)\n \n 0\n \n 0\n
\n \\(979\\)\n \n 0\n \n 0\n
\n \\(980\\)\n \n 0\n \n 0\n
\n \\(981\\)\n \n \u22121.00000\n \n +\n \n 1.00000i\n \u22121.00000\n \n +\n \n 1.00000i
\n \\(982\\)\n \n 0\n \n 0\n
\n \\(983\\)\n \n 0\n \n 0\n \n \u22120.258819\n \n \u2212\n \n 0.965926i\n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \\(0.416667\\pi\\)\n
\n \\(984\\)\n \n 0\n \n 0\n
\n \\(985\\)\n \n \u22121.00000\n \n \u2212\n \n 1.73205i\n \u22121.00000\n \n \u2212\n \n 1.73205i
\n \\(986\\)\n \n \u22121.00000\n \n \u2212\n \n 1.00000i\n \u22121.00000\n \n \u2212\n \n 1.00000i
\n \\(987\\)\n \n 0\n \n 0\n
\n \\(988\\)\n \n 0\n \n 0\n
\n \\(989\\)\n \n 0\n \n 0\n
\n \\(990\\)\n \n 0\n \n 0\n
\n \\(991\\)\n \n 0\n \n 0\n \n \u22120.258819\n \n \u2212\n \n 0.965926i\n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \\(0.416667\\pi\\)\n
\n \\(992\\)\n \n 0\n \n 0\n
\n \\(993\\)\n \n 0\n \n 0\n
\n \\(994\\)\n \n 0\n \n 0\n
\n \\(995\\)\n \n 0\n \n 0\n
\n \\(996\\)\n \n 0\n \n 0\n
\n \\(997\\)\n \n 1.36603\n \n \u2212\n \n 0.366025i\n 1.36603\n \n \u2212\n \n 0.366025i\n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(998\\)\n \n 0\n \n 0\n
\n \\(999\\)\n \n 0\n \n 0\n
", "content": {"html": "
\\(n\\)\\(a_n\\)\\(a_n / n^{(k-1)/2}\\)\\( \\alpha_n \\)\\( \\theta_n \\)
\\(p\\)\\(a_p\\)\\(a_p / p^{(k-1)/2}\\)\\( \\alpha_p\\)\\( \\theta_p \\)
\\(2\\)\u22120.866025+0.500000<br>i\u22120.866025+0.500000<br>i
\\(3\\)00\u22120.258819\u22120.965926<br>i\\(-0.583333\\pi\\)
0.258819+0.965926<br>i\\(0.416667\\pi\\)
\\(4\\)0.500000\u22120.866025<br>i0.500000\u22120.866025<br>i
\\(5\\)\u22121.36603\u22120.366025<br>i\u22121.36603\u22120.366025<br>i\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(6\\)00
\\(7\\)00
\\(8\\)1.00000<br>i1.00000<br>i
\\(9\\)\u22120.866025+0.500000<br>i\u22120.866025+0.500000<br>i
\\(10\\)1.36603\u22120.366025<br>i1.36603\u22120.366025<br>i
\\(11\\)000.965926\u22120.258819<br>i\\(-0.0833333\\pi\\)
\u22120.965926+0.258819<br>i\\(0.916667\\pi\\)
\\(12\\)00
\\(13\\)00\u22121.00000<br>i\\(-0.5\\pi\\)
1.00000<br>i\\(0.5\\pi\\)
\\(14\\)00
\\(15\\)00
\\(16\\)\u22120.500000\u22120.866025<br>i\u22120.500000\u22120.866025<br>i
\\(17\\)\u22120.500000+0.866025<br>i\u22120.500000+0.866025<br>i
\\(18\\)0.500000\u22120.866025<br>i0.500000\u22120.866025<br>i
\\(19\\)000.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(20\\)\u22121.00000+1.00000<br>i\u22121.00000+1.00000<br>i
\\(21\\)00
\\(22\\)00
\\(23\\)000.258819\u22120.965926<br>i\\(-0.416667\\pi\\)
\u22120.258819+0.965926<br>i\\(0.583333\\pi\\)
\\(24\\)00
\\(25\\)0.866025+0.500000<br>i0.866025+0.500000<br>i
\\(26\\)00
\\(27\\)00
\\(28\\)00
\\(29\\)1.00000\u22121.00000<br>i1.00000\u22121.00000<br>i\u22121.00000<br>i\\(-0.5\\pi\\)
1.00000\\(0\\)
\\(30\\)00
\\(31\\)00\u22120.258819\u22120.965926<br>i\\(-0.583333\\pi\\)
0.258819+0.965926<br>i\\(0.416667\\pi\\)
\\(32\\)0.866025+0.500000<br>i0.866025+0.500000<br>i
\\(33\\)00
\\(34\\)\u22121.00000<br>i\u22121.00000<br>i
\\(35\\)00
\\(36\\)1.00000<br>i1.00000<br>i
\\(37\\)1.36603+0.366025<br>i1.36603+0.366025<br>i0.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
0.500000+0.866025<br>i\\(0.333333\\pi\\)
\\(38\\)00
\\(39\\)00
\\(40\\)0.366025\u22121.36603<br>i0.366025\u22121.36603<br>i
\\(41\\)\u22121.00000\u22121.00000<br>i\u22121.00000\u22121.00000<br>i\u22121.00000<br>i\\(-0.5\\pi\\)
\u22121.00000\\(\\pi\\)
\\(42\\)00
\\(43\\)00\u22121.00000<br>i\\(-0.5\\pi\\)
1.00000<br>i\\(0.5\\pi\\)
\\(44\\)00
\\(45\\)1.36603\u22120.366025<br>i1.36603\u22120.366025<br>i
\\(46\\)00
\\(47\\)00\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
0.500000+0.866025<br>i\\(0.333333\\pi\\)
\\(48\\)00
\\(49\\)00
\\(50\\)\u22121.00000\u22121.00000
\\(51\\)00
\\(52\\)00
\\(53\\)000.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
\u22120.500000+0.866025<br>i\\(0.666667\\pi\\)
\\(54\\)00
\\(55\\)00
\\(56\\)00
\\(57\\)00
\\(58\\)\u22120.366025+1.36603<br>i\u22120.366025+1.36603<br>i
\\(59\\)00\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
0.866025+0.500000<br>i\\(0.166667\\pi\\)
\\(60\\)00
\\(61\\)0.366025\u22121.36603<br>i0.366025\u22121.36603<br>i\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
0.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
\\(62\\)00
\\(63\\)00
\\(64\\)\u22121.00000\u22121.00000
\\(65\\)00
\\(66\\)00
\\(67\\)000.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
\u22120.500000+0.866025<br>i\\(0.666667\\pi\\)
\\(68\\)0.500000+0.866025<br>i0.500000+0.866025<br>i
\\(69\\)00
\\(70\\)00
\\(71\\)000.707107\u22120.707107<br>i\\(-0.250000\\pi\\)
\u22120.707107+0.707107<br>i\\(0.750000\\pi\\)
\\(72\\)\u22120.500000\u22120.866025<br>i\u22120.500000\u22120.866025<br>i
\\(73\\)\u22120.366025\u22121.36603<br>i\u22120.366025\u22121.36603<br>i\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
0.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
\\(74\\)\u22121.36603+0.366025<br>i\u22121.36603+0.366025<br>i
\\(75\\)00
\\(76\\)00
\\(77\\)00
\\(78\\)00
\\(79\\)000.258819\u22120.965926<br>i\\(-0.416667\\pi\\)
\u22120.258819+0.965926<br>i\\(0.583333\\pi\\)
\\(80\\)0.366025+1.36603<br>i0.366025+1.36603<br>i
\\(81\\)0.500000\u22120.866025<br>i0.500000\u22120.866025<br>i
\\(82\\)1.36603+0.366025<br>i1.36603+0.366025<br>i
\\(83\\)00\u22121.00000<br>i\\(-0.5\\pi\\)
1.00000<br>i\\(0.5\\pi\\)
\\(84\\)00
\\(85\\)1.00000\u22121.00000<br>i1.00000\u22121.00000<br>i
\\(86\\)00
\\(87\\)00
\\(88\\)00
\\(89\\)000.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(90\\)\u22121.00000+1.00000<br>i\u22121.00000+1.00000<br>i
\\(91\\)00
\\(92\\)00
\\(93\\)00
\\(94\\)00
\\(95\\)00
\\(96\\)00
\\(97\\)1.00000\u22121.00000<br>i1.00000\u22121.00000<br>i\u22121.00000<br>i\\(-0.5\\pi\\)
1.00000\\(0\\)
\\(98\\)00
\\(99\\)00
\\(100\\)0.866025\u22120.500000<br>i0.866025\u22120.500000<br>i
\\(101\\)00\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
0.866025+0.500000<br>i\\(0.166667\\pi\\)
\\(102\\)00
\\(103\\)00\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
0.500000+0.866025<br>i\\(0.333333\\pi\\)
\\(104\\)00
\\(105\\)00
\\(106\\)00
\\(107\\)00\u22120.965926\u22120.258819<br>i\\(-0.916667\\pi\\)
0.965926+0.258819<br>i\\(0.0833333\\pi\\)
\\(108\\)00
\\(109\\)1.36603\u22120.366025<br>i1.36603\u22120.366025<br>i0.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
0.866025+0.500000<br>i\\(0.166667\\pi\\)
\\(110\\)00
\\(111\\)00
\\(112\\)00
\\(113\\)\u22121.00000\u22121.00000<br>i\u22121.00000\u22121.00000<br>i\u22121.00000<br>i\\(-0.5\\pi\\)
\u22121.00000\\(\\pi\\)
\\(114\\)00
\\(115\\)00
\\(116\\)\u22120.366025\u22121.36603<br>i\u22120.366025\u22121.36603<br>i
\\(117\\)00
\\(118\\)00
\\(119\\)00
\\(120\\)00
\\(121\\)0.866025\u22120.500000<br>i0.866025\u22120.500000<br>i
\\(122\\)0.366025+1.36603<br>i0.366025+1.36603<br>i
\\(123\\)00
\\(124\\)00
\\(125\\)00
\\(126\\)00
\\(127\\)00\u22121.00000<br>i\\(-0.5\\pi\\)
1.00000<br>i\\(0.5\\pi\\)
\\(128\\)0.866025\u22120.500000<br>i0.866025\u22120.500000<br>i
\\(129\\)00
\\(130\\)00
\\(131\\)00\u22120.965926\u22120.258819<br>i\\(-0.916667\\pi\\)
0.965926+0.258819<br>i\\(0.0833333\\pi\\)
\\(132\\)00
\\(133\\)00
\\(134\\)00
\\(135\\)00
\\(136\\)\u22120.866025\u22120.500000<br>i\u22120.866025\u22120.500000<br>i
\\(137\\)00\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
0.866025+0.500000<br>i\\(0.166667\\pi\\)
\\(138\\)00
\\(139\\)000.707107\u22120.707107<br>i\\(-0.250000\\pi\\)
\u22120.707107+0.707107<br>i\\(0.750000\\pi\\)
\\(140\\)00
\\(141\\)00
\\(142\\)00
\\(143\\)00
\\(144\\)0.866025+0.500000<br>i0.866025+0.500000<br>i
\\(145\\)\u22121.73205+1.00000<br>i\u22121.73205+1.00000<br>i
\\(146\\)1.00000+1.00000<br>i1.00000+1.00000<br>i
\\(147\\)00
\\(148\\)1.00000\u22121.00000<br>i1.00000\u22121.00000<br>i
\\(149\\)\u22121.00000\u22121.73205<br>i\u22121.00000\u22121.73205<br>i\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
\\(150\\)00
\\(151\\)00\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
0.866025+0.500000<br>i\\(0.166667\\pi\\)
\\(152\\)00
\\(153\\)\u22121.00000<br>i\u22121.00000<br>i
\\(154\\)00
\\(155\\)00
\\(156\\)00
\\(157\\)1.00000\u22121.73205<br>i1.00000\u22121.73205<br>i0.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
0.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
\\(158\\)00
\\(159\\)00
\\(160\\)\u22121.00000\u22121.00000<br>i\u22121.00000\u22121.00000<br>i
\\(161\\)00
\\(162\\)1.00000<br>i1.00000<br>i
\\(163\\)000.258819\u22120.965926<br>i\\(-0.416667\\pi\\)
\u22120.258819+0.965926<br>i\\(0.583333\\pi\\)
\\(164\\)\u22121.36603+0.366025<br>i\u22121.36603+0.366025<br>i
\\(165\\)00
\\(166\\)00
\\(167\\)000.707107\u22120.707107<br>i\\(-0.250000\\pi\\)
\u22120.707107+0.707107<br>i\\(0.750000\\pi\\)
\\(168\\)00
\\(169\\)\u22121.00000\u22121.00000
\\(170\\)\u22120.366025+1.36603<br>i\u22120.366025+1.36603<br>i
\\(171\\)00
\\(172\\)00
\\(173\\)1.36603+0.366025<br>i1.36603+0.366025<br>i0.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
0.500000+0.866025<br>i\\(0.333333\\pi\\)
\\(174\\)00
\\(175\\)00
\\(176\\)00
\\(177\\)00
\\(178\\)00
\\(179\\)00\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
0.866025+0.500000<br>i\\(0.166667\\pi\\)
\\(180\\)0.366025\u22121.36603<br>i0.366025\u22121.36603<br>i
\\(181\\)1.00000+1.00000<br>i1.00000+1.00000<br>i1.00000\\(0\\)
1.00000<br>i\\(0.5\\pi\\)
\\(182\\)00
\\(183\\)00
\\(184\\)00
\\(185\\)\u22121.73205\u22121.00000<br>i\u22121.73205\u22121.00000<br>i
\\(186\\)00
\\(187\\)00
\\(188\\)00
\\(189\\)00
\\(190\\)00
\\(191\\)00\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
0.500000+0.866025<br>i\\(0.333333\\pi\\)
\\(192\\)00
\\(193\\)\u22121.36603+0.366025<br>i\u22121.36603+0.366025<br>i\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
\u22120.500000+0.866025<br>i\\(0.666667\\pi\\)
\\(194\\)\u22120.366025+1.36603<br>i\u22120.366025+1.36603<br>i
\\(195\\)00
\\(196\\)00
\\(197\\)1.00000+1.00000<br>i1.00000+1.00000<br>i1.00000\\(0\\)
1.00000<br>i\\(0.5\\pi\\)
\\(198\\)00
\\(199\\)00\u22120.258819\u22120.965926<br>i\\(-0.583333\\pi\\)
0.258819+0.965926<br>i\\(0.416667\\pi\\)
\\(200\\)\u22120.500000+0.866025<br>i\u22120.500000+0.866025<br>i
\\(201\\)00
\\(202\\)00
\\(203\\)00
\\(204\\)00
\\(205\\)1.00000+1.73205<br>i1.00000+1.73205<br>i
\\(206\\)00
\\(207\\)00
\\(208\\)00
\\(209\\)00
\\(210\\)00
\\(211\\)00\u22120.707107\u22120.707107<br>i\\(-0.750000\\pi\\)
0.707107+0.707107<br>i\\(0.250000\\pi\\)
\\(212\\)00
\\(213\\)00
\\(214\\)00
\\(215\\)00
\\(216\\)00
\\(217\\)00
\\(218\\)\u22121.00000+1.00000<br>i\u22121.00000+1.00000<br>i
\\(219\\)00
\\(220\\)00
\\(221\\)00
\\(222\\)00
\\(223\\)00\u22121.00000<br>i\\(-0.5\\pi\\)
1.00000<br>i\\(0.5\\pi\\)
\\(224\\)00
\\(225\\)\u22121.00000\u22121.00000
\\(226\\)1.36603+0.366025<br>i1.36603+0.366025<br>i
\\(227\\)000.965926\u22120.258819<br>i\\(-0.0833333\\pi\\)
\u22120.965926+0.258819<br>i\\(0.916667\\pi\\)
\\(228\\)00
\\(229\\)\u22121.73205+1.00000<br>i\u22121.73205+1.00000<br>i\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(230\\)00
\\(231\\)00
\\(232\\)1.00000+1.00000<br>i1.00000+1.00000<br>i
\\(233\\)1.36603+0.366025<br>i1.36603+0.366025<br>i0.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
0.500000+0.866025<br>i\\(0.333333\\pi\\)
\\(234\\)00
\\(235\\)00
\\(236\\)00
\\(237\\)00
\\(238\\)00
\\(239\\)001.00000\\(0\\)
\u22121.00000\\(\\pi\\)
\\(240\\)00
\\(241\\)\u22120.366025\u22121.36603<br>i\u22120.366025\u22121.36603<br>i\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
0.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
\\(242\\)\u22120.500000+0.866025<br>i\u22120.500000+0.866025<br>i
\\(243\\)00
\\(244\\)\u22121.00000\u22121.00000<br>i\u22121.00000\u22121.00000<br>i
\\(245\\)00
\\(246\\)00
\\(247\\)00
\\(248\\)00
\\(249\\)00
\\(250\\)00
\\(251\\)001.00000\\(0\\)
\u22121.00000\\(\\pi\\)
\\(252\\)00
\\(253\\)00
\\(254\\)00
\\(255\\)00
\\(256\\)\u22120.500000+0.866025<br>i\u22120.500000+0.866025<br>i
\\(257\\)1.73205\u22121.00000<br>i1.73205\u22121.00000<br>i0.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
0.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
\\(258\\)00
\\(259\\)00
\\(260\\)00
\\(261\\)\u22120.366025+1.36603<br>i\u22120.366025+1.36603<br>i
\\(262\\)00
\\(263\\)00\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
0.866025+0.500000<br>i\\(0.166667\\pi\\)
\\(264\\)00
\\(265\\)00
\\(266\\)00
\\(267\\)00
\\(268\\)00
\\(269\\)0.366025+1.36603<br>i0.366025+1.36603<br>i0.866025+0.500000<br>i\\(0.166667\\pi\\)
\u22120.500000+0.866025<br>i\\(0.666667\\pi\\)
\\(270\\)00
\\(271\\)00\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
0.500000+0.866025<br>i\\(0.333333\\pi\\)
\\(272\\)1.000001.00000
\\(273\\)00
\\(274\\)00
\\(275\\)00
\\(276\\)00
\\(277\\)0.366025+1.36603<br>i0.366025+1.36603<br>i0.866025+0.500000<br>i\\(0.166667\\pi\\)
\u22120.500000+0.866025<br>i\\(0.666667\\pi\\)
\\(278\\)00
\\(279\\)00
\\(280\\)00
\\(281\\)001.00000\\(0\\)
\u22121.00000\\(\\pi\\)
\\(282\\)00
\\(283\\)000.965926\u22120.258819<br>i\\(-0.0833333\\pi\\)
\u22120.965926+0.258819<br>i\\(0.916667\\pi\\)
\\(284\\)00
\\(285\\)00
\\(286\\)00
\\(287\\)00
\\(288\\)\u22121.00000\u22121.00000
\\(289\\)\u22120.500000\u22120.866025<br>i\u22120.500000\u22120.866025<br>i
\\(290\\)1.00000\u22121.73205<br>i1.00000\u22121.73205<br>i
\\(291\\)00
\\(292\\)\u22121.36603\u22120.366025<br>i\u22121.36603\u22120.366025<br>i
\\(293\\)2.000002.000001.00000\\(0\\)
1.00000\\(0\\)
\\(294\\)00
\\(295\\)00
\\(296\\)\u22120.366025+1.36603<br>i\u22120.366025+1.36603<br>i
\\(297\\)00
\\(298\\)1.73205+1.00000<br>i1.73205+1.00000<br>i
\\(299\\)00
\\(300\\)00
\\(301\\)00
\\(302\\)00
\\(303\\)00
\\(304\\)00
\\(305\\)\u22121.00000+1.73205<br>i\u22121.00000+1.73205<br>i
\\(306\\)0.500000+0.866025<br>i0.500000+0.866025<br>i
\\(307\\)001.00000\\(0\\)
\u22121.00000\\(\\pi\\)
\\(308\\)00
\\(309\\)00
\\(310\\)00
\\(311\\)00\u22120.258819\u22120.965926<br>i\\(-0.583333\\pi\\)
0.258819+0.965926<br>i\\(0.416667\\pi\\)
\\(312\\)00
\\(313\\)\u22120.366025+1.36603<br>i\u22120.366025+1.36603<br>i0.500000+0.866025<br>i\\(0.333333\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(314\\)2.00000<br>i2.00000<br>i
\\(315\\)00
\\(316\\)00
\\(317\\)0.366025\u22121.36603<br>i0.366025\u22121.36603<br>i\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
0.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
\\(318\\)00
\\(319\\)00
\\(320\\)1.36603+0.366025<br>i1.36603+0.366025<br>i
\\(321\\)00
\\(322\\)00
\\(323\\)00
\\(324\\)\u22120.500000\u22120.866025<br>i\u22120.500000\u22120.866025<br>i
\\(325\\)00
\\(326\\)00
\\(327\\)00
\\(328\\)1.00000\u22121.00000<br>i1.00000\u22121.00000<br>i
\\(329\\)00
\\(330\\)00
\\(331\\)000.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(332\\)00
\\(333\\)\u22121.36603+0.366025<br>i\u22121.36603+0.366025<br>i
\\(334\\)00
\\(335\\)00
\\(336\\)00
\\(337\\)1.00000\u22121.00000<br>i1.00000\u22121.00000<br>i\u22121.00000<br>i\\(-0.5\\pi\\)
1.00000\\(0\\)
\\(338\\)0.866025\u22120.500000<br>i0.866025\u22120.500000<br>i
\\(339\\)00
\\(340\\)\u22120.366025\u22121.36603<br>i\u22120.366025\u22121.36603<br>i
\\(341\\)00
\\(342\\)00
\\(343\\)00
\\(344\\)00
\\(345\\)00
\\(346\\)\u22121.36603+0.366025<br>i\u22121.36603+0.366025<br>i
\\(347\\)000.965926\u22120.258819<br>i\\(-0.0833333\\pi\\)
\u22120.965926+0.258819<br>i\\(0.916667\\pi\\)
\\(348\\)00
\\(349\\)001.00000\\(0\\)
\u22121.00000\\(\\pi\\)
\\(350\\)00
\\(351\\)00
\\(352\\)00
\\(353\\)\u22121.00000+1.73205<br>i\u22121.00000+1.73205<br>i\u22120.500000+0.866025<br>i\\(0.666667\\pi\\)
\u22120.500000+0.866025<br>i\\(0.666667\\pi\\)
\\(354\\)00
\\(355\\)00
\\(356\\)00
\\(357\\)00
\\(358\\)00
\\(359\\)000.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(360\\)0.366025+1.36603<br>i0.366025+1.36603<br>i
\\(361\\)0.500000\u22120.866025<br>i0.500000\u22120.866025<br>i
\\(362\\)\u22121.36603\u22120.366025<br>i\u22121.36603\u22120.366025<br>i
\\(363\\)00
\\(364\\)00
\\(365\\)2.00000<br>i2.00000<br>i
\\(366\\)00
\\(367\\)000.965926\u22120.258819<br>i\\(-0.0833333\\pi\\)
\u22120.965926+0.258819<br>i\\(0.916667\\pi\\)
\\(368\\)00
\\(369\\)1.36603+0.366025<br>i1.36603+0.366025<br>i
\\(370\\)2.000002.00000
\\(371\\)00
\\(372\\)00
\\(373\\)000.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(374\\)00
\\(375\\)00
\\(376\\)00
\\(377\\)00
\\(378\\)00
\\(379\\)000.707107\u22120.707107<br>i\\(-0.250000\\pi\\)
\u22120.707107+0.707107<br>i\\(0.750000\\pi\\)
\\(380\\)00
\\(381\\)00
\\(382\\)00
\\(383\\)000.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(384\\)00
\\(385\\)00
\\(386\\)1.00000\u22121.00000<br>i1.00000\u22121.00000<br>i
\\(387\\)00
\\(388\\)\u22120.366025\u22121.36603<br>i\u22120.366025\u22121.36603<br>i
\\(389\\)\u22121.73205\u22121.00000<br>i\u22121.73205\u22121.00000<br>i\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
\\(390\\)00
\\(391\\)00
\\(392\\)00
\\(393\\)00
\\(394\\)\u22121.36603\u22120.366025<br>i\u22121.36603\u22120.366025<br>i
\\(395\\)00
\\(396\\)00
\\(397\\)0.366025\u22121.36603<br>i0.366025\u22121.36603<br>i\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
0.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
\\(398\\)00
\\(399\\)00
\\(400\\)\u22121.00000<br>i\u22121.00000<br>i
\\(401\\)0.366025\u22121.36603<br>i0.366025\u22121.36603<br>i\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
0.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
\\(402\\)00
\\(403\\)00
\\(404\\)00
\\(405\\)\u22121.00000+1.00000<br>i\u22121.00000+1.00000<br>i
\\(406\\)00
\\(407\\)00
\\(408\\)00
\\(409\\)\u22121.00000+1.73205<br>i\u22121.00000+1.73205<br>i\u22120.500000+0.866025<br>i\\(0.666667\\pi\\)
\u22120.500000+0.866025<br>i\\(0.666667\\pi\\)
\\(410\\)\u22121.73205\u22121.00000<br>i\u22121.73205\u22121.00000<br>i
\\(411\\)00
\\(412\\)00
\\(413\\)00
\\(414\\)00
\\(415\\)00
\\(416\\)00
\\(417\\)00
\\(418\\)00
\\(419\\)00\u22120.707107\u22120.707107<br>i\\(-0.750000\\pi\\)
0.707107+0.707107<br>i\\(0.250000\\pi\\)
\\(420\\)00
\\(421\\)00\u22121.00000<br>i\\(-0.5\\pi\\)
1.00000<br>i\\(0.5\\pi\\)
\\(422\\)00
\\(423\\)00
\\(424\\)00
\\(425\\)\u22120.866025+0.500000<br>i\u22120.866025+0.500000<br>i
\\(426\\)00
\\(427\\)00
\\(428\\)00
\\(429\\)00
\\(430\\)00
\\(431\\)000.965926\u22120.258819<br>i\\(-0.0833333\\pi\\)
\u22120.965926+0.258819<br>i\\(0.916667\\pi\\)
\\(432\\)00
\\(433\\)2.00000<br>i2.00000<br>i1.00000<br>i\\(0.5\\pi\\)
1.00000<br>i\\(0.5\\pi\\)
\\(434\\)00
\\(435\\)00
\\(436\\)0.366025\u22121.36603<br>i0.366025\u22121.36603<br>i
\\(437\\)00
\\(438\\)00
\\(439\\)00\u22120.965926\u22120.258819<br>i\\(-0.916667\\pi\\)
0.965926+0.258819<br>i\\(0.0833333\\pi\\)
\\(440\\)00
\\(441\\)00
\\(442\\)00
\\(443\\)00\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
0.500000+0.866025<br>i\\(0.333333\\pi\\)
\\(444\\)00
\\(445\\)00
\\(446\\)00
\\(447\\)00
\\(448\\)00
\\(449\\)\u22121.00000\u22121.00000<br>i\u22121.00000\u22121.00000<br>i\u22121.00000<br>i\\(-0.5\\pi\\)
\u22121.00000\\(\\pi\\)
\\(450\\)0.866025\u22120.500000<br>i0.866025\u22120.500000<br>i
\\(451\\)00
\\(452\\)\u22121.36603+0.366025<br>i\u22121.36603+0.366025<br>i
\\(453\\)00
\\(454\\)00
\\(455\\)00
\\(456\\)00
\\(457\\)\u22121.73205+1.00000<br>i\u22121.73205+1.00000<br>i\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(458\\)1.00000\u22121.73205<br>i1.00000\u22121.73205<br>i
\\(459\\)00
\\(460\\)00
\\(461\\)001.00000\\(0\\)
\u22121.00000\\(\\pi\\)
\\(462\\)00
\\(463\\)001.00000\\(0\\)
\u22121.00000\\(\\pi\\)
\\(464\\)\u22121.36603\u22120.366025<br>i\u22121.36603\u22120.366025<br>i
\\(465\\)00
\\(466\\)\u22121.36603+0.366025<br>i\u22121.36603+0.366025<br>i
\\(467\\)000.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(468\\)00
\\(469\\)00
\\(470\\)00
\\(471\\)00
\\(472\\)00
\\(473\\)00
\\(474\\)00
\\(475\\)00
\\(476\\)00
\\(477\\)00
\\(478\\)00
\\(479\\)00\u22120.258819\u22120.965926<br>i\\(-0.583333\\pi\\)
0.258819+0.965926<br>i\\(0.416667\\pi\\)
\\(480\\)00
\\(481\\)00
\\(482\\)1.00000+1.00000<br>i1.00000+1.00000<br>i
\\(483\\)00
\\(484\\)\u22121.00000<br>i\u22121.00000<br>i
\\(485\\)\u22121.73205+1.00000<br>i\u22121.73205+1.00000<br>i
\\(486\\)00
\\(487\\)000.965926\u22120.258819<br>i\\(-0.0833333\\pi\\)
\u22120.965926+0.258819<br>i\\(0.916667\\pi\\)
\\(488\\)1.36603+0.366025<br>i1.36603+0.366025<br>i
\\(489\\)00
\\(490\\)00
\\(491\\)00\u22121.00000<br>i\\(-0.5\\pi\\)
1.00000<br>i\\(0.5\\pi\\)
\\(492\\)00
\\(493\\)0.366025+1.36603<br>i0.366025+1.36603<br>i
\\(494\\)00
\\(495\\)00
\\(496\\)00
\\(497\\)00
\\(498\\)00
\\(499\\)000.258819\u22120.965926<br>i\\(-0.416667\\pi\\)
\u22120.258819+0.965926<br>i\\(0.583333\\pi\\)
\\(500\\)00
\\(501\\)00
\\(502\\)00
\\(503\\)00\u22120.707107\u22120.707107<br>i\\(-0.750000\\pi\\)
0.707107+0.707107<br>i\\(0.250000\\pi\\)
\\(504\\)00
\\(505\\)00
\\(506\\)00
\\(507\\)00
\\(508\\)00
\\(509\\)\u22121.00000\u22121.73205<br>i\u22121.00000\u22121.73205<br>i\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
\\(510\\)00
\\(511\\)00
\\(512\\)\u22121.00000<br>i\u22121.00000<br>i
\\(513\\)00
\\(514\\)\u22121.00000+1.73205<br>i\u22121.00000+1.73205<br>i
\\(515\\)00
\\(516\\)00
\\(517\\)00
\\(518\\)00
\\(519\\)00
\\(520\\)00
\\(521\\)1.36603\u22120.366025<br>i1.36603\u22120.366025<br>i0.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
0.866025+0.500000<br>i\\(0.166667\\pi\\)
\\(522\\)\u22120.366025\u22121.36603<br>i\u22120.366025\u22121.36603<br>i
\\(523\\)00\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
0.500000+0.866025<br>i\\(0.333333\\pi\\)
\\(524\\)00
\\(525\\)00
\\(526\\)00
\\(527\\)00
\\(528\\)00
\\(529\\)\u22120.866025\u22120.500000<br>i\u22120.866025\u22120.500000<br>i
\\(530\\)00
\\(531\\)00
\\(532\\)00
\\(533\\)00
\\(534\\)00
\\(535\\)00
\\(536\\)00
\\(537\\)00
\\(538\\)\u22121.00000\u22121.00000<br>i\u22121.00000\u22121.00000<br>i
\\(539\\)00
\\(540\\)00
\\(541\\)1.36603+0.366025<br>i1.36603+0.366025<br>i0.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
0.500000+0.866025<br>i\\(0.333333\\pi\\)
\\(542\\)00
\\(543\\)00
\\(544\\)\u22120.866025+0.500000<br>i\u22120.866025+0.500000<br>i
\\(545\\)\u22122.00000\u22122.00000
\\(546\\)00
\\(547\\)000.707107\u22120.707107<br>i\\(-0.250000\\pi\\)
\u22120.707107+0.707107<br>i\\(0.750000\\pi\\)
\\(548\\)00
\\(549\\)0.366025+1.36603<br>i0.366025+1.36603<br>i
\\(550\\)00
\\(551\\)00
\\(552\\)00
\\(553\\)00
\\(554\\)\u22121.00000\u22121.00000<br>i\u22121.00000\u22121.00000<br>i
\\(555\\)00
\\(556\\)00
\\(557\\)00\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
0.866025+0.500000<br>i\\(0.166667\\pi\\)
\\(558\\)00
\\(559\\)00
\\(560\\)00
\\(561\\)00
\\(562\\)00
\\(563\\)00\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
0.866025+0.500000<br>i\\(0.166667\\pi\\)
\\(564\\)00
\\(565\\)1.00000+1.73205<br>i1.00000+1.73205<br>i
\\(566\\)00
\\(567\\)00
\\(568\\)00
\\(569\\)00\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
0.500000+0.866025<br>i\\(0.333333\\pi\\)
\\(570\\)00
\\(571\\)000.965926\u22120.258819<br>i\\(-0.0833333\\pi\\)
\u22120.965926+0.258819<br>i\\(0.916667\\pi\\)
\\(572\\)00
\\(573\\)00
\\(574\\)00
\\(575\\)00
\\(576\\)0.866025\u22120.500000<br>i0.866025\u22120.500000<br>i
\\(577\\)00\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
0.866025+0.500000<br>i\\(0.166667\\pi\\)
\\(578\\)0.866025+0.500000<br>i0.866025+0.500000<br>i
\\(579\\)00
\\(580\\)2.00000<br>i2.00000<br>i
\\(581\\)00
\\(582\\)00
\\(583\\)00
\\(584\\)1.36603\u22120.366025<br>i1.36603\u22120.366025<br>i
\\(585\\)00
\\(586\\)\u22121.73205+1.00000<br>i\u22121.73205+1.00000<br>i
\\(587\\)00\u22121.00000<br>i\\(-0.5\\pi\\)
1.00000<br>i\\(0.5\\pi\\)
\\(588\\)00
\\(589\\)00
\\(590\\)00
\\(591\\)00
\\(592\\)\u22120.366025\u22121.36603<br>i\u22120.366025\u22121.36603<br>i
\\(593\\)00\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
0.500000+0.866025<br>i\\(0.333333\\pi\\)
\\(594\\)00
\\(595\\)00
\\(596\\)\u22122.00000\u22122.00000
\\(597\\)00
\\(598\\)00
\\(599\\)000.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
\u22120.500000+0.866025<br>i\\(0.666667\\pi\\)
\\(600\\)00
\\(601\\)\u22121.00000\u22121.00000<br>i\u22121.00000\u22121.00000<br>i\u22121.00000<br>i\\(-0.5\\pi\\)
\u22121.00000\\(\\pi\\)
\\(602\\)00
\\(603\\)00
\\(604\\)00
\\(605\\)\u22121.36603+0.366025<br>i\u22121.36603+0.366025<br>i
\\(606\\)00
\\(607\\)00\u22120.965926\u22120.258819<br>i\\(-0.916667\\pi\\)
0.965926+0.258819<br>i\\(0.0833333\\pi\\)
\\(608\\)00
\\(609\\)00
\\(610\\)\u22122.00000<br>i\u22122.00000<br>i
\\(611\\)00
\\(612\\)\u22120.866025\u22120.500000<br>i\u22120.866025\u22120.500000<br>i
\\(613\\)\u22121.00000+1.73205<br>i\u22121.00000+1.73205<br>i\u22120.500000+0.866025<br>i\\(0.666667\\pi\\)
\u22120.500000+0.866025<br>i\\(0.666667\\pi\\)
\\(614\\)00
\\(615\\)00
\\(616\\)00
\\(617\\)\u22121.00000+1.00000<br>i\u22121.00000+1.00000<br>i1.00000<br>i\\(0.5\\pi\\)
\u22121.00000\\(\\pi\\)
\\(618\\)00
\\(619\\)000.965926\u22120.258819<br>i\\(-0.0833333\\pi\\)
\u22120.965926+0.258819<br>i\\(0.916667\\pi\\)
\\(620\\)00
\\(621\\)00
\\(622\\)00
\\(623\\)00
\\(624\\)00
\\(625\\)\u22120.500000\u22120.866025<br>i\u22120.500000\u22120.866025<br>i
\\(626\\)\u22120.366025\u22121.36603<br>i\u22120.366025\u22121.36603<br>i
\\(627\\)00
\\(628\\)\u22121.00000\u22121.73205<br>i\u22121.00000\u22121.73205<br>i
\\(629\\)\u22121.00000+1.00000<br>i\u22121.00000+1.00000<br>i
\\(630\\)00
\\(631\\)00\u22121.00000<br>i\\(-0.5\\pi\\)
1.00000<br>i\\(0.5\\pi\\)
\\(632\\)00
\\(633\\)00
\\(634\\)0.366025+1.36603<br>i0.366025+1.36603<br>i
\\(635\\)00
\\(636\\)00
\\(637\\)00
\\(638\\)00
\\(639\\)00
\\(640\\)\u22121.36603+0.366025<br>i\u22121.36603+0.366025<br>i
\\(641\\)\u22120.366025\u22121.36603<br>i\u22120.366025\u22121.36603<br>i\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
0.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
\\(642\\)00
\\(643\\)000.707107\u22120.707107<br>i\\(-0.250000\\pi\\)
\u22120.707107+0.707107<br>i\\(0.750000\\pi\\)
\\(644\\)00
\\(645\\)00
\\(646\\)00
\\(647\\)000.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
\u22120.500000+0.866025<br>i\\(0.666667\\pi\\)
\\(648\\)0.866025+0.500000<br>i0.866025+0.500000<br>i
\\(649\\)00
\\(650\\)00
\\(651\\)00
\\(652\\)00
\\(653\\)0.366025\u22121.36603<br>i0.366025\u22121.36603<br>i\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
0.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
\\(654\\)00
\\(655\\)00
\\(656\\)\u22120.366025+1.36603<br>i\u22120.366025+1.36603<br>i
\\(657\\)1.00000+1.00000<br>i1.00000+1.00000<br>i
\\(658\\)00
\\(659\\)001.00000\\(0\\)
\u22121.00000\\(\\pi\\)
\\(660\\)00
\\(661\\)000.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
\u22120.500000+0.866025<br>i\\(0.666667\\pi\\)
\\(662\\)00
\\(663\\)00
\\(664\\)00
\\(665\\)00
\\(666\\)1.00000\u22121.00000<br>i1.00000\u22121.00000<br>i
\\(667\\)00
\\(668\\)00
\\(669\\)00
\\(670\\)00
\\(671\\)00
\\(672\\)00
\\(673\\)\u22121.00000\u22121.00000<br>i\u22121.00000\u22121.00000<br>i\u22121.00000<br>i\\(-0.5\\pi\\)
\u22121.00000\\(\\pi\\)
\\(674\\)\u22120.366025+1.36603<br>i\u22120.366025+1.36603<br>i
\\(675\\)00
\\(676\\)\u22120.500000+0.866025<br>i\u22120.500000+0.866025<br>i
\\(677\\)1.36603+0.366025<br>i1.36603+0.366025<br>i0.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
0.500000+0.866025<br>i\\(0.333333\\pi\\)
\\(678\\)00
\\(679\\)00
\\(680\\)1.00000+1.00000<br>i1.00000+1.00000<br>i
\\(681\\)00
\\(682\\)00
\\(683\\)00\u22120.258819\u22120.965926<br>i\\(-0.583333\\pi\\)
0.258819+0.965926<br>i\\(0.416667\\pi\\)
\\(684\\)00
\\(685\\)00
\\(686\\)00
\\(687\\)00
\\(688\\)00
\\(689\\)00
\\(690\\)00
\\(691\\)000.258819\u22120.965926<br>i\\(-0.416667\\pi\\)
\u22120.258819+0.965926<br>i\\(0.583333\\pi\\)
\\(692\\)1.00000\u22121.00000<br>i1.00000\u22121.00000<br>i
\\(693\\)00
\\(694\\)00
\\(695\\)00
\\(696\\)00
\\(697\\)1.36603\u22120.366025<br>i1.36603\u22120.366025<br>i
\\(698\\)00
\\(699\\)00
\\(700\\)00
\\(701\\)00\u22121.00000<br>i\\(-0.5\\pi\\)
1.00000<br>i\\(0.5\\pi\\)
\\(702\\)00
\\(703\\)00
\\(704\\)00
\\(705\\)00
\\(706\\)\u22122.00000<br>i\u22122.00000<br>i
\\(707\\)00
\\(708\\)00
\\(709\\)\u22121.36603\u22120.366025<br>i\u22121.36603\u22120.366025<br>i\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(710\\)00
\\(711\\)00
\\(712\\)00
\\(713\\)00
\\(714\\)00
\\(715\\)00
\\(716\\)00
\\(717\\)00
\\(718\\)00
\\(719\\)00\u22120.965926\u22120.258819<br>i\\(-0.916667\\pi\\)
0.965926+0.258819<br>i\\(0.0833333\\pi\\)
\\(720\\)\u22121.00000\u22121.00000<br>i\u22121.00000\u22121.00000<br>i
\\(721\\)00
\\(722\\)1.00000<br>i1.00000<br>i
\\(723\\)00
\\(724\\)1.36603\u22120.366025<br>i1.36603\u22120.366025<br>i
\\(725\\)1.36603\u22120.366025<br>i1.36603\u22120.366025<br>i
\\(726\\)00
\\(727\\)001.00000\\(0\\)
\u22121.00000\\(\\pi\\)
\\(728\\)00
\\(729\\)1.00000<br>i1.00000<br>i
\\(730\\)\u22121.00000\u22121.73205<br>i\u22121.00000\u22121.73205<br>i
\\(731\\)00
\\(732\\)00
\\(733\\)00\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
0.500000+0.866025<br>i\\(0.333333\\pi\\)
\\(734\\)00
\\(735\\)00
\\(736\\)00
\\(737\\)00
\\(738\\)\u22121.36603+0.366025<br>i\u22121.36603+0.366025<br>i
\\(739\\)00\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
0.866025+0.500000<br>i\\(0.166667\\pi\\)
\\(740\\)\u22121.73205+1.00000<br>i\u22121.73205+1.00000<br>i
\\(741\\)00
\\(742\\)00
\\(743\\)000.707107\u22120.707107<br>i\\(-0.250000\\pi\\)
\u22120.707107+0.707107<br>i\\(0.750000\\pi\\)
\\(744\\)00
\\(745\\)0.732051+2.73205<br>i0.732051+2.73205<br>i
\\(746\\)00
\\(747\\)00
\\(748\\)00
\\(749\\)00
\\(750\\)00
\\(751\\)00\u22120.965926\u22120.258819<br>i\\(-0.916667\\pi\\)
0.965926+0.258819<br>i\\(0.0833333\\pi\\)
\\(752\\)00
\\(753\\)00
\\(754\\)00
\\(755\\)00
\\(756\\)00
\\(757\\)2.00000<br>i2.00000<br>i1.00000<br>i\\(0.5\\pi\\)
1.00000<br>i\\(0.5\\pi\\)
\\(758\\)00
\\(759\\)00
\\(760\\)00
\\(761\\)000.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(762\\)00
\\(763\\)00
\\(764\\)00
\\(765\\)\u22120.366025+1.36603<br>i\u22120.366025+1.36603<br>i
\\(766\\)00
\\(767\\)00
\\(768\\)00
\\(769\\)00\u22121.00000<br>i\\(-0.5\\pi\\)
1.00000<br>i\\(0.5\\pi\\)
\\(770\\)00
\\(771\\)00
\\(772\\)\u22120.366025+1.36603<br>i\u22120.366025+1.36603<br>i
\\(773\\)\u22121.73205\u22121.00000<br>i\u22121.73205\u22121.00000<br>i\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
\\(774\\)00
\\(775\\)00
\\(776\\)1.00000+1.00000<br>i1.00000+1.00000<br>i
\\(777\\)00
\\(778\\)2.000002.00000
\\(779\\)00
\\(780\\)00
\\(781\\)00
\\(782\\)00
\\(783\\)00
\\(784\\)00
\\(785\\)\u22122.00000+2.00000<br>i\u22122.00000+2.00000<br>i
\\(786\\)00
\\(787\\)00\u22120.258819\u22120.965926<br>i\\(-0.583333\\pi\\)
0.258819+0.965926<br>i\\(0.416667\\pi\\)
\\(788\\)1.36603\u22120.366025<br>i1.36603\u22120.366025<br>i
\\(789\\)00
\\(790\\)00
\\(791\\)00
\\(792\\)00
\\(793\\)00
\\(794\\)0.366025+1.36603<br>i0.366025+1.36603<br>i
\\(795\\)00
\\(796\\)00
\\(797\\)001.00000\\(0\\)
\u22121.00000\\(\\pi\\)
\\(798\\)00
\\(799\\)00
\\(800\\)0.500000+0.866025<br>i0.500000+0.866025<br>i
\\(801\\)00
\\(802\\)0.366025+1.36603<br>i0.366025+1.36603<br>i
\\(803\\)00
\\(804\\)00
\\(805\\)00
\\(806\\)00
\\(807\\)00
\\(808\\)00
\\(809\\)1.36603\u22120.366025<br>i1.36603\u22120.366025<br>i0.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
0.866025+0.500000<br>i\\(0.166667\\pi\\)
\\(810\\)0.366025\u22121.36603<br>i0.366025\u22121.36603<br>i
\\(811\\)000.707107\u22120.707107<br>i\\(-0.250000\\pi\\)
\u22120.707107+0.707107<br>i\\(0.750000\\pi\\)
\\(812\\)00
\\(813\\)00
\\(814\\)00
\\(815\\)00
\\(816\\)00
\\(817\\)00
\\(818\\)\u22122.00000<br>i\u22122.00000<br>i
\\(819\\)00
\\(820\\)2.000002.00000
\\(821\\)\u22121.36603\u22120.366025<br>i\u22121.36603\u22120.366025<br>i\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(822\\)00
\\(823\\)000.965926\u22120.258819<br>i\\(-0.0833333\\pi\\)
\u22120.965926+0.258819<br>i\\(0.916667\\pi\\)
\\(824\\)00
\\(825\\)00
\\(826\\)00
\\(827\\)00\u22120.707107\u22120.707107<br>i\\(-0.750000\\pi\\)
0.707107+0.707107<br>i\\(0.250000\\pi\\)
\\(828\\)00
\\(829\\)1.00000\u22121.73205<br>i1.00000\u22121.73205<br>i0.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
0.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
\\(830\\)00
\\(831\\)00
\\(832\\)00
\\(833\\)00
\\(834\\)00
\\(835\\)00
\\(836\\)00
\\(837\\)00
\\(838\\)00
\\(839\\)00\u22120.707107\u22120.707107<br>i\\(-0.750000\\pi\\)
0.707107+0.707107<br>i\\(0.250000\\pi\\)
\\(840\\)00
\\(841\\)\u22121.00000<br>i\u22121.00000<br>i
\\(842\\)00
\\(843\\)00
\\(844\\)00
\\(845\\)1.36603+0.366025<br>i1.36603+0.366025<br>i
\\(846\\)00
\\(847\\)00
\\(848\\)00
\\(849\\)00
\\(850\\)0.500000\u22120.866025<br>i0.500000\u22120.866025<br>i
\\(851\\)00
\\(852\\)00
\\(853\\)1.00000\u22121.00000<br>i1.00000\u22121.00000<br>i\u22121.00000<br>i\\(-0.5\\pi\\)
1.00000\\(0\\)
\\(854\\)00
\\(855\\)00
\\(856\\)00
\\(857\\)1.36603\u22120.366025<br>i1.36603\u22120.366025<br>i0.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
0.866025+0.500000<br>i\\(0.166667\\pi\\)
\\(858\\)00
\\(859\\)000.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(860\\)00
\\(861\\)00
\\(862\\)00
\\(863\\)00\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
0.500000+0.866025<br>i\\(0.333333\\pi\\)
\\(864\\)00
\\(865\\)\u22121.73205\u22121.00000<br>i\u22121.73205\u22121.00000<br>i
\\(866\\)\u22121.00000\u22121.73205<br>i\u22121.00000\u22121.73205<br>i
\\(867\\)00
\\(868\\)00
\\(869\\)00
\\(870\\)00
\\(871\\)00
\\(872\\)0.366025+1.36603<br>i0.366025+1.36603<br>i
\\(873\\)\u22120.366025+1.36603<br>i\u22120.366025+1.36603<br>i
\\(874\\)00
\\(875\\)00
\\(876\\)00
\\(877\\)\u22120.366025+1.36603<br>i\u22120.366025+1.36603<br>i0.500000+0.866025<br>i\\(0.333333\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(878\\)00
\\(879\\)00
\\(880\\)00
\\(881\\)\u22121.00000+1.00000<br>i\u22121.00000+1.00000<br>i1.00000<br>i\\(0.5\\pi\\)
\u22121.00000\\(\\pi\\)
\\(882\\)00
\\(883\\)001.00000\\(0\\)
\u22121.00000\\(\\pi\\)
\\(884\\)00
\\(885\\)00
\\(886\\)00
\\(887\\)00\u22120.965926\u22120.258819<br>i\\(-0.916667\\pi\\)
0.965926+0.258819<br>i\\(0.0833333\\pi\\)
\\(888\\)00
\\(889\\)00
\\(890\\)00
\\(891\\)00
\\(892\\)00
\\(893\\)00
\\(894\\)00
\\(895\\)00
\\(896\\)00
\\(897\\)00
\\(898\\)1.36603+0.366025<br>i1.36603+0.366025<br>i
\\(899\\)00
\\(900\\)\u22120.500000+0.866025<br>i\u22120.500000+0.866025<br>i
\\(901\\)00
\\(902\\)00
\\(903\\)00
\\(904\\)1.00000\u22121.00000<br>i1.00000\u22121.00000<br>i
\\(905\\)\u22121.00000\u22121.73205<br>i\u22121.00000\u22121.73205<br>i
\\(906\\)00
\\(907\\)000.965926\u22120.258819<br>i\\(-0.0833333\\pi\\)
\u22120.965926+0.258819<br>i\\(0.916667\\pi\\)
\\(908\\)00
\\(909\\)00
\\(910\\)00
\\(911\\)00\u22120.707107\u22120.707107<br>i\\(-0.750000\\pi\\)
0.707107+0.707107<br>i\\(0.250000\\pi\\)
\\(912\\)00
\\(913\\)00
\\(914\\)1.00000\u22121.73205<br>i1.00000\u22121.73205<br>i
\\(915\\)00
\\(916\\)2.00000<br>i2.00000<br>i
\\(917\\)00
\\(918\\)00
\\(919\\)00\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
0.500000+0.866025<br>i\\(0.333333\\pi\\)
\\(920\\)00
\\(921\\)00
\\(922\\)00
\\(923\\)00
\\(924\\)00
\\(925\\)1.00000+1.00000<br>i1.00000+1.00000<br>i
\\(926\\)00
\\(927\\)00
\\(928\\)1.36603\u22120.366025<br>i1.36603\u22120.366025<br>i
\\(929\\)\u22120.366025+1.36603<br>i\u22120.366025+1.36603<br>i0.500000+0.866025<br>i\\(0.333333\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(930\\)00
\\(931\\)00
\\(932\\)1.00000\u22121.00000<br>i1.00000\u22121.00000<br>i
\\(933\\)00
\\(934\\)00
\\(935\\)00
\\(936\\)00
\\(937\\)001.00000\\(0\\)
\u22121.00000\\(\\pi\\)
\\(938\\)00
\\(939\\)00
\\(940\\)00
\\(941\\)1.36603\u22120.366025<br>i1.36603\u22120.366025<br>i0.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
0.866025+0.500000<br>i\\(0.166667\\pi\\)
\\(942\\)00
\\(943\\)00
\\(944\\)00
\\(945\\)00
\\(946\\)00
\\(947\\)00\u22120.965926\u22120.258819<br>i\\(-0.916667\\pi\\)
0.965926+0.258819<br>i\\(0.0833333\\pi\\)
\\(948\\)00
\\(949\\)00
\\(950\\)00
\\(951\\)00
\\(952\\)00
\\(953\\)00\u22121.00000<br>i\\(-0.5\\pi\\)
1.00000<br>i\\(0.5\\pi\\)
\\(954\\)00
\\(955\\)00
\\(956\\)00
\\(957\\)00
\\(958\\)00
\\(959\\)00
\\(960\\)00
\\(961\\)\u22120.866025+0.500000<br>i\u22120.866025+0.500000<br>i
\\(962\\)00
\\(963\\)00
\\(964\\)\u22121.36603\u22120.366025<br>i\u22121.36603\u22120.366025<br>i
\\(965\\)2.000002.00000
\\(966\\)00
\\(967\\)00\u22121.00000<br>i\\(-0.5\\pi\\)
1.00000<br>i\\(0.5\\pi\\)
\\(968\\)0.500000+0.866025<br>i0.500000+0.866025<br>i
\\(969\\)00
\\(970\\)1.00000\u22121.73205<br>i1.00000\u22121.73205<br>i
\\(971\\)000.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(972\\)00
\\(973\\)00
\\(974\\)00
\\(975\\)00
\\(976\\)\u22121.36603+0.366025<br>i\u22121.36603+0.366025<br>i
\\(977\\)000.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
\u22120.500000+0.866025<br>i\\(0.666667\\pi\\)
\\(978\\)00
\\(979\\)00
\\(980\\)00
\\(981\\)\u22121.00000+1.00000<br>i\u22121.00000+1.00000<br>i
\\(982\\)00
\\(983\\)00\u22120.258819\u22120.965926<br>i\\(-0.583333\\pi\\)
0.258819+0.965926<br>i\\(0.416667\\pi\\)
\\(984\\)00
\\(985\\)\u22121.00000\u22121.73205<br>i\u22121.00000\u22121.73205<br>i
\\(986\\)\u22121.00000\u22121.00000<br>i\u22121.00000\u22121.00000<br>i
\\(987\\)00
\\(988\\)00
\\(989\\)00
\\(990\\)00
\\(991\\)00\u22120.258819\u22120.965926<br>i\\(-0.583333\\pi\\)
0.258819+0.965926<br>i\\(0.416667\\pi\\)
\\(992\\)00
\\(993\\)00
\\(994\\)00
\\(995\\)00
\\(996\\)00
\\(997\\)1.36603\u22120.366025<br>i1.36603\u22120.366025<br>i0.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
0.866025+0.500000<br>i\\(0.166667\\pi\\)
\\(998\\)00
\\(999\\)00
", "is_complex": true, "table_nest_level": "1"}}, {"type": "paragraph", "raw_content": "
\n (See \\(a_n\\) instead)\n
", "content": [{"c": "( See \\(a_n\\) instead)", "t": "text"}]}, {"type": "paragraph", "raw_content": "
\n (See \\(a_n\\) instead)\n
", "content": [{"c": "( See \\(a_n\\) instead)", "t": "text"}]}, {"type": "paragraph", "raw_content": "
\n (See \\(a_n\\) instead)\n
", "content": [{"c": "( See \\(a_n\\) instead)", "t": "text"}]}, {"type": "paragraph", "raw_content": "
\n (See only \\(a_p\\))\n
", "content": [{"c": "( See only \\(a_p\\))", "t": "text"}]}, {"type": "paragraph", "raw_content": "
\n (See only \\(a_p\\))\n
", "content": [{"c": "( See only \\(a_p\\))", "t": "text"}]}, {"type": "paragraph", "raw_content": "
\n (See only \\(a_p\\))\n
", "content": [{"c": "( See only \\(a_p\\))", "t": "text"}]}, {"type": "table", "raw_content": "
\u2003\u2003\u2003\u2003\u2003\u2003\u2003By twisting character
CharParityOrdTypeTwistMinDim
1.1even1trivial3332.1.bc.b.2027.14
4.3odd2CM3332.1.bc.b.2027.14
7.2even3inner3332.1.bc.b.667.14
7.3odd668.1.f.a.55.1yes2
7.4even33332.1.m.b.2843.12
7.5odd63332.1.bc.c.667.14
7.6odd23332.1.bc.c.2027.14
17.13even4inner3332.1.bc.b.2223.14
21.17even6612.1.l.a.55.12
28.3even668.1.f.a.55.1yes2
28.11odd63332.1.m.b.2843.12
28.19even63332.1.bc.c.667.14
28.23odd6inner3332.1.bc.b.667.14
28.27even23332.1.bc.c.2027.14
35.3even121700.1.n.a.599.12
35.17even121700.1.n.b.599.12
35.24odd61700.1.p.a.1551.12
56.3even61088.1.p.a.191.12
56.45odd61088.1.p.a.191.12
68.47odd4inner3332.1.bc.b.2223.14
84.59odd6612.1.l.a.55.12
119.3even481156.1.g.b.155.18
119.10even481156.1.g.b.179.18
119.13odd43332.1.bc.c.2223.14
119.24even481156.1.g.b.179.28
119.30even12inner3332.1.bc.b.863.14
119.31even481156.1.g.b.155.28
119.38odd121156.1.f.b.251.12
119.45even481156.1.g.b.399.18
119.47odd123332.1.bc.c.863.14
119.59odd241156.1.c.b.579.12
119.66odd241156.1.d.a.1155.22
119.73even481156.1.g.b.423.28
119.80even481156.1.g.b.423.18
119.81even123332.1.m.b.3039.12
119.87odd241156.1.d.a.1155.12
119.94odd241156.1.c.b.579.22
119.101odd61156.1.f.b.327.12
119.108even481156.1.g.b.399.28
119.115odd1268.1.f.a.47.1&check;2
140.3odd121700.1.n.a.599.12
140.59even61700.1.p.a.1551.12
140.87odd121700.1.n.b.599.12
357.353even12612.1.l.a.523.12
476.3odd481156.1.g.b.155.18
476.31odd481156.1.g.b.155.28
476.47even123332.1.bc.c.863.14
476.59even241156.1.c.b.579.12
476.87even241156.1.d.a.1155.12
476.115even1268.1.f.a.47.1&check;2
476.143odd481156.1.g.b.179.28
476.199odd481156.1.g.b.423.18
476.227odd481156.1.g.b.399.28
476.251even43332.1.bc.c.2223.14
476.283odd481156.1.g.b.399.18
476.311odd481156.1.g.b.423.28
476.319odd123332.1.m.b.3039.12
476.339even61156.1.f.b.327.12
476.367odd481156.1.g.b.179.18
476.387odd12inner3332.1.bc.b.863.14
476.395even121156.1.f.b.251.12
476.423even241156.1.d.a.1155.22
476.451even241156.1.c.b.579.22
595.234odd121700.1.p.a.251.12
595.353even121700.1.n.b.999.12
595.472even121700.1.n.a.999.12
952.115even121088.1.p.a.319.12
952.829odd121088.1.p.a.319.12
1428.1067odd12612.1.l.a.523.12
2380.1067odd121700.1.n.a.999.12
2380.1543odd121700.1.n.b.999.12
2380.2019even121700.1.p.a.251.12
", "content": {"html": "
By<br>twisting character
CharParityOrdTypeTwistMinDim
1.1even1trivial3332.1.bc.b.2027.14
4.3odd2CM3332.1.bc.b.2027.14
7.2even3inner3332.1.bc.b.667.14
7.3odd668.1.f.a.55.1yes2
7.4even33332.1.m.b.2843.12
7.5odd63332.1.bc.c.667.14
7.6odd23332.1.bc.c.2027.14
17.13even4inner3332.1.bc.b.2223.14
21.17even6612.1.l.a.55.12
28.3even668.1.f.a.55.1yes2
28.11odd63332.1.m.b.2843.12
28.19even63332.1.bc.c.667.14
28.23odd6inner3332.1.bc.b.667.14
28.27even23332.1.bc.c.2027.14
35.3even121700.1.n.a.599.12
35.17even121700.1.n.b.599.12
35.24odd61700.1.p.a.1551.12
56.3even61088.1.p.a.191.12
56.45odd61088.1.p.a.191.12
68.47odd4inner3332.1.bc.b.2223.14
84.59odd6612.1.l.a.55.12
119.3even481156.1.g.b.155.18
119.10even481156.1.g.b.179.18
119.13odd43332.1.bc.c.2223.14
119.24even481156.1.g.b.179.28
119.30even12inner3332.1.bc.b.863.14
119.31even481156.1.g.b.155.28
119.38odd121156.1.f.b.251.12
119.45even481156.1.g.b.399.18
119.47odd123332.1.bc.c.863.14
119.59odd241156.1.c.b.579.12
119.66odd241156.1.d.a.1155.22
119.73even481156.1.g.b.423.28
119.80even481156.1.g.b.423.18
119.81even123332.1.m.b.3039.12
119.87odd241156.1.d.a.1155.12
119.94odd241156.1.c.b.579.22
119.101odd61156.1.f.b.327.12
119.108even481156.1.g.b.399.28
119.115odd1268.1.f.a.47.1&check;2
140.3odd121700.1.n.a.599.12
140.59even61700.1.p.a.1551.12
140.87odd121700.1.n.b.599.12
357.353even12612.1.l.a.523.12
476.3odd481156.1.g.b.155.18
476.31odd481156.1.g.b.155.28
476.47even123332.1.bc.c.863.14
476.59even241156.1.c.b.579.12
476.87even241156.1.d.a.1155.12
476.115even1268.1.f.a.47.1&check;2
476.143odd481156.1.g.b.179.28
476.199odd481156.1.g.b.423.18
476.227odd481156.1.g.b.399.28
476.251even43332.1.bc.c.2223.14
476.283odd481156.1.g.b.399.18
476.311odd481156.1.g.b.423.28
476.319odd123332.1.m.b.3039.12
476.339even61156.1.f.b.327.12
476.367odd481156.1.g.b.179.18
476.387odd12inner3332.1.bc.b.863.14
476.395even121156.1.f.b.251.12
476.423even241156.1.d.a.1155.22
476.451even241156.1.c.b.579.22
595.234odd121700.1.p.a.251.12
595.353even121700.1.n.b.999.12
595.472even121700.1.n.a.999.12
952.115even121088.1.p.a.319.12
952.829odd121088.1.p.a.319.12
1428.1067odd12612.1.l.a.523.12
2380.1067odd121700.1.n.a.999.12
2380.1543odd121700.1.n.b.999.12
2380.2019even121700.1.p.a.251.12
", "is_complex": true, "table_nest_level": "1"}}, {"type": "table", "raw_content": "
\u2003\u2003\u2003\u2003\u2003\u2003\u2003\u2003By twisted newform
TwistMinDimCharParityOrdType
68.1.f.a.47.1&check;2119.115odd12
68.1.f.a.47.1&check;2476.115even12
68.1.f.a.55.1yes27.3odd6
68.1.f.a.55.1yes228.3even6
612.1.l.a.55.1221.17even6
612.1.l.a.55.1284.59odd6
612.1.l.a.523.12357.353even12
612.1.l.a.523.121428.1067odd12
1088.1.p.a.191.1256.3even6
1088.1.p.a.191.1256.45odd6
1088.1.p.a.319.12952.115even12
1088.1.p.a.319.12952.829odd12
1156.1.c.b.579.12119.59odd24
1156.1.c.b.579.12476.59even24
1156.1.c.b.579.22119.94odd24
1156.1.c.b.579.22476.451even24
1156.1.d.a.1155.12119.87odd24
1156.1.d.a.1155.12476.87even24
1156.1.d.a.1155.22119.66odd24
1156.1.d.a.1155.22476.423even24
1156.1.f.b.251.12119.38odd12
1156.1.f.b.251.12476.395even12
1156.1.f.b.327.12119.101odd6
1156.1.f.b.327.12476.339even6
1156.1.g.b.155.18119.3even48
1156.1.g.b.155.18476.3odd48
1156.1.g.b.155.28119.31even48
1156.1.g.b.155.28476.31odd48
1156.1.g.b.179.18119.10even48
1156.1.g.b.179.18476.367odd48
1156.1.g.b.179.28119.24even48
1156.1.g.b.179.28476.143odd48
1156.1.g.b.399.18119.45even48
1156.1.g.b.399.18476.283odd48
1156.1.g.b.399.28119.108even48
1156.1.g.b.399.28476.227odd48
1156.1.g.b.423.18119.80even48
1156.1.g.b.423.18476.199odd48
1156.1.g.b.423.28119.73even48
1156.1.g.b.423.28476.311odd48
1700.1.n.a.599.1235.3even12
1700.1.n.a.599.12140.3odd12
1700.1.n.a.999.12595.472even12
1700.1.n.a.999.122380.1067odd12
1700.1.n.b.599.1235.17even12
1700.1.n.b.599.12140.87odd12
1700.1.n.b.999.12595.353even12
1700.1.n.b.999.122380.1543odd12
1700.1.p.a.251.12595.234odd12
1700.1.p.a.251.122380.2019even12
1700.1.p.a.1551.1235.24odd6
1700.1.p.a.1551.12140.59even6
3332.1.m.b.2843.127.4even3
3332.1.m.b.2843.1228.11odd6
3332.1.m.b.3039.12119.81even12
3332.1.m.b.3039.12476.319odd12
3332.1.bc.b.667.147.2even3inner
3332.1.bc.b.667.1428.23odd6inner
3332.1.bc.b.863.14119.30even12inner
3332.1.bc.b.863.14476.387odd12inner
3332.1.bc.b.2027.141.1even1trivial
3332.1.bc.b.2027.144.3odd2CM
3332.1.bc.b.2223.1417.13even4inner
3332.1.bc.b.2223.1468.47odd4inner
3332.1.bc.c.667.147.5odd6
3332.1.bc.c.667.1428.19even6
3332.1.bc.c.863.14119.47odd12
3332.1.bc.c.863.14476.47even12
3332.1.bc.c.2027.147.6odd2
3332.1.bc.c.2027.1428.27even2
3332.1.bc.c.2223.14119.13odd4
3332.1.bc.c.2223.14476.251even4
", "content": {"html": "
By<br>twisted newform
TwistMinDimCharParityOrdType
68.1.f.a.47.1&check;2119.115odd12
68.1.f.a.47.1&check;2476.115even12
68.1.f.a.55.1yes27.3odd6
68.1.f.a.55.1yes228.3even6
612.1.l.a.55.1221.17even6
612.1.l.a.55.1284.59odd6
612.1.l.a.523.12357.353even12
612.1.l.a.523.121428.1067odd12
1088.1.p.a.191.1256.3even6
1088.1.p.a.191.1256.45odd6
1088.1.p.a.319.12952.115even12
1088.1.p.a.319.12952.829odd12
1156.1.c.b.579.12119.59odd24
1156.1.c.b.579.12476.59even24
1156.1.c.b.579.22119.94odd24
1156.1.c.b.579.22476.451even24
1156.1.d.a.1155.12119.87odd24
1156.1.d.a.1155.12476.87even24
1156.1.d.a.1155.22119.66odd24
1156.1.d.a.1155.22476.423even24
1156.1.f.b.251.12119.38odd12
1156.1.f.b.251.12476.395even12
1156.1.f.b.327.12119.101odd6
1156.1.f.b.327.12476.339even6
1156.1.g.b.155.18119.3even48
1156.1.g.b.155.18476.3odd48
1156.1.g.b.155.28119.31even48
1156.1.g.b.155.28476.31odd48
1156.1.g.b.179.18119.10even48
1156.1.g.b.179.18476.367odd48
1156.1.g.b.179.28119.24even48
1156.1.g.b.179.28476.143odd48
1156.1.g.b.399.18119.45even48
1156.1.g.b.399.18476.283odd48
1156.1.g.b.399.28119.108even48
1156.1.g.b.399.28476.227odd48
1156.1.g.b.423.18119.80even48
1156.1.g.b.423.18476.199odd48
1156.1.g.b.423.28119.73even48
1156.1.g.b.423.28476.311odd48
1700.1.n.a.599.1235.3even12
1700.1.n.a.599.12140.3odd12
1700.1.n.a.999.12595.472even12
1700.1.n.a.999.122380.1067odd12
1700.1.n.b.599.1235.17even12
1700.1.n.b.599.12140.87odd12
1700.1.n.b.999.12595.353even12
1700.1.n.b.999.122380.1543odd12
1700.1.p.a.251.12595.234odd12
1700.1.p.a.251.122380.2019even12
1700.1.p.a.1551.1235.24odd6
1700.1.p.a.1551.12140.59even6
3332.1.m.b.2843.127.4even3
3332.1.m.b.2843.1228.11odd6
3332.1.m.b.3039.12119.81even12
3332.1.m.b.3039.12476.319odd12
3332.1.bc.b.667.147.2even3inner
3332.1.bc.b.667.1428.23odd6inner
3332.1.bc.b.863.14119.30even12inner
3332.1.bc.b.863.14476.387odd12inner
3332.1.bc.b.2027.141.1even1trivial
3332.1.bc.b.2027.144.3odd2CM
3332.1.bc.b.2223.1417.13even4inner
3332.1.bc.b.2223.1468.47odd4inner
3332.1.bc.c.667.147.5odd6
3332.1.bc.c.667.1428.19even6
3332.1.bc.c.863.14119.47odd12
3332.1.bc.c.863.14476.47even12
3332.1.bc.c.2027.147.6odd2
3332.1.bc.c.2027.1428.27even2
3332.1.bc.c.2223.14119.13odd4
3332.1.bc.c.2223.14476.251even4
", "is_complex": true, "table_nest_level": "1"}}]], "main_html": "
\n Show commands:\n Magma\n / PariGP\n / SageMath
[N,k,chi] = [3332,1,Mod(667,3332)]
mf = mfinit([N,k,chi],0)
lf = mfeigenbasis(mf)
from sage.modular.dirichlet import DirichletCharacter
H = DirichletGroup(3332, base_ring=CyclotomicField(12))
chi = DirichletCharacter(H, H._module([6, 4, 9]))
N = Newforms(chi, 1, names=\"a\")
//Please install CHIMP (https://github.com/edgarcosta/CHIMP) if you want to run this code
chi := DirichletCharacter(\"3332.667\");
S:= CuspForms(chi, 1);
N := Newforms(S);
Level: \\( N \\) \\(=\\)\\( 3332 = 2^{2} \\cdot 7^{2} \\cdot 17 \\)
Weight: \\( k \\) \\(=\\)\\( 1 \\)
Character orbit: \\([\\chi]\\) \\(=\\)3332.bc (of order \\(12\\), degree \\(4\\), not minimal)

Newform invariants

sage:\u00a0f = N[0] # Warning: the index may be different
gp:\u00a0f = lf[1] \\\\ Warning: the index may be different
Self dual: no
Analytic conductor: \\(1.66288462209\\)
Analytic rank: \\(0\\)
Dimension: \\(4\\)
Coefficient field: \\(\\Q(\\zeta_{12})\\)
gp:\u00a0f.mod \\\\ as an extension of the character field
Defining polynomial: \\( x^{4} - x^{2} + 1 \\)\"Copy\"Toggle
Coefficient ring: \\(\\Z[a_1, a_2]\\)
Coefficient ring index: \\( 1 \\)
Twist minimal: no (minimal twist has level 68)
Projective image:\\(D_{4}\\)
Projective field:Galois closure of 4.2.19652.1
Artin image:$C_4\\wr C_2\\times C_6$
Artin field:Galois closure of \\(\\mathbb{Q}[x]/(x^{48} - \\cdots)\\)

Embedding invariants

Embedding label 2027.1
Root\\(0.866025 - 0.500000i\\) of defining polynomial
Character\\(\\chi\\)\\(=\\)3332.2027
Dual form3332.1.bc.b.863.1
sage:\u00a0f.q_expansion() # note that sage often uses an isomorphic number field
gp:\u00a0mfcoefs(f, 20)
\\(f(q)\\)\\(=\\)\\(q+(-0.866025 + 0.500000i) q^{2} +(0.500000 - 0.866025i) q^{4} +(-1.36603 - 0.366025i) q^{5} +1.00000i q^{8} +(-0.866025 + 0.500000i) q^{9} +(1.36603 - 0.366025i) q^{10} +(-0.500000 - 0.866025i) q^{16} +(-0.500000 + 0.866025i) q^{17} +(0.500000 - 0.866025i) q^{18} +(-1.00000 + 1.00000i) q^{20} +(0.866025 + 0.500000i) q^{25} +(1.00000 - 1.00000i) q^{29} +(0.866025 + 0.500000i) q^{32} -1.00000i q^{34} +1.00000i q^{36} +(1.36603 + 0.366025i) q^{37} +(0.366025 - 1.36603i) q^{40} +(-1.00000 - 1.00000i) q^{41} +(1.36603 - 0.366025i) q^{45} -1.00000 q^{50} +(-0.366025 + 1.36603i) q^{58} +(0.366025 - 1.36603i) q^{61} -1.00000 q^{64} +(0.500000 + 0.866025i) q^{68} +(-0.500000 - 0.866025i) q^{72} +(-0.366025 - 1.36603i) q^{73} +(-1.36603 + 0.366025i) q^{74} +(0.366025 + 1.36603i) q^{80} +(0.500000 - 0.866025i) q^{81} +(1.36603 + 0.366025i) q^{82} +(1.00000 - 1.00000i) q^{85} +(-1.00000 + 1.00000i) q^{90} +(1.00000 - 1.00000i) q^{97} +O(q^{100})\\)
\\(\\operatorname{Tr}(f)(q)\\)\\(=\\)\\( 4 q + 2 q^{4} - 2 q^{5} + 2 q^{10} - 2 q^{16} - 2 q^{17} + 2 q^{18} - 4 q^{20} + 4 q^{29} + 2 q^{37} - 2 q^{40} - 4 q^{41} + 2 q^{45} - 4 q^{50} + 2 q^{58} - 2 q^{61} - 4 q^{64} + 2 q^{68} - 2 q^{72} + 2 q^{73}+ \\cdots + 4 q^{97}+O(q^{100}) \\)\"Copy\"Toggle

Character values

We give the values of \\chi on generators for \\left(\\mathbb{Z}/3332\\mathbb{Z}\\right)^\\times.

\\(n\\)\\(785\\)\\(885\\)\\(1667\\)
\\(\\chi(n)\\)\\(e\\left(\\frac{3}{4}\\right)\\)\\(e\\left(\\frac{2}{3}\\right)\\)\\(-1\\)

Coefficient data

For each \\(n\\) we display the coefficients of the \\(q\\)-expansion \\(a_n\\), the\nSatake parameters \\(\\alpha_p\\),\nand the Satake angles \\(\\theta_p = \\textrm{Arg}(\\alpha_p)\\).

\n (See \\(a_n\\) instead)\n
\n (See \\(a_n\\) instead)\n
\n (See \\(a_n\\) instead)\n
\n (See only \\(a_p\\))\n
\n (See only \\(a_p\\))\n
\n (See only \\(a_p\\))\n
\n \\(n\\)\n \n \\(a_n\\)\n \n \\(a_n / n^{(k-1)/2}\\)\n \n \\( \\alpha_n \\)\n \n \\( \\theta_n \\)\n
\n \\(p\\)\n \n \\(a_p\\)\n \n \\(a_p / p^{(k-1)/2}\\)\n \n \\( \\alpha_p\\)\n \n \\( \\theta_p \\)\n
\n \\(2\\)\n \n \u22120.866025\n \n +\n \n 0.500000i\n \u22120.866025\n \n +\n \n 0.500000i
\n \\(3\\)\n \n 0\n \n 0\n \n \u22120.258819\n \n \u2212\n \n 0.965926i\n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \\(0.416667\\pi\\)\n
\n \\(4\\)\n \n 0.500000\n \n \u2212\n \n 0.866025i\n 0.500000\n \n \u2212\n \n 0.866025i
\n \\(5\\)\n \n \u22121.36603\n \n \u2212\n \n 0.366025i\n \u22121.36603\n \n \u2212\n \n 0.366025i\n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(6\\)\n \n 0\n \n 0\n
\n \\(7\\)\n \n 0\n \n 0\n
\n \\(8\\)\n \n 1.00000i\n 1.00000i
\n \\(9\\)\n \n \u22120.866025\n \n +\n \n 0.500000i\n \u22120.866025\n \n +\n \n 0.500000i
\n \\(10\\)\n \n 1.36603\n \n \u2212\n \n 0.366025i\n 1.36603\n \n \u2212\n \n 0.366025i
\n \\(11\\)\n \n 0\n \n 0\n \n 0.965926\n \n \u2212\n \n 0.258819i\n \\(-0.0833333\\pi\\)\n
\n \u22120.965926\n \n +\n \n 0.258819i\n \\(0.916667\\pi\\)\n
\n \\(12\\)\n \n 0\n \n 0\n
\n \\(13\\)\n \n 0\n \n 0\n \n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(14\\)\n \n 0\n \n 0\n
\n \\(15\\)\n \n 0\n \n 0\n
\n \\(16\\)\n \n \u22120.500000\n \n \u2212\n \n 0.866025i\n \u22120.500000\n \n \u2212\n \n 0.866025i
\n \\(17\\)\n \n \u22120.500000\n \n +\n \n 0.866025i\n \u22120.500000\n \n +\n \n 0.866025i
\n \\(18\\)\n \n 0.500000\n \n \u2212\n \n 0.866025i\n 0.500000\n \n \u2212\n \n 0.866025i
\n \\(19\\)\n \n 0\n \n 0\n \n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(20\\)\n \n \u22121.00000\n \n +\n \n 1.00000i\n \u22121.00000\n \n +\n \n 1.00000i
\n \\(21\\)\n \n 0\n \n 0\n
\n \\(22\\)\n \n 0\n \n 0\n
\n \\(23\\)\n \n 0\n \n 0\n \n 0.258819\n \n \u2212\n \n 0.965926i\n \\(-0.416667\\pi\\)\n
\n \u22120.258819\n \n +\n \n 0.965926i\n \\(0.583333\\pi\\)\n
\n \\(24\\)\n \n 0\n \n 0\n
\n \\(25\\)\n \n 0.866025\n \n +\n \n 0.500000i\n 0.866025\n \n +\n \n 0.500000i
\n \\(26\\)\n \n 0\n \n 0\n
\n \\(27\\)\n \n 0\n \n 0\n
\n \\(28\\)\n \n 0\n \n 0\n
\n \\(29\\)\n \n 1.00000\n \n \u2212\n \n 1.00000i\n 1.00000\n \n \u2212\n \n 1.00000i\n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000\n \n \\(0\\)\n
\n \\(30\\)\n \n 0\n \n 0\n
\n \\(31\\)\n \n 0\n \n 0\n \n \u22120.258819\n \n \u2212\n \n 0.965926i\n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \\(0.416667\\pi\\)\n
\n \\(32\\)\n \n 0.866025\n \n +\n \n 0.500000i\n 0.866025\n \n +\n \n 0.500000i
\n \\(33\\)\n \n 0\n \n 0\n
\n \\(34\\)\n \n \u2212\n \n 1.00000i\n \u2212\n \n 1.00000i
\n \\(35\\)\n \n 0\n \n 0\n
\n \\(36\\)\n \n 1.00000i\n 1.00000i
\n \\(37\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i\n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(38\\)\n \n 0\n \n 0\n
\n \\(39\\)\n \n 0\n \n 0\n
\n \\(40\\)\n \n 0.366025\n \n \u2212\n \n 1.36603i\n 0.366025\n \n \u2212\n \n 1.36603i
\n \\(41\\)\n \n \u22121.00000\n \n \u2212\n \n 1.00000i\n \u22121.00000\n \n \u2212\n \n 1.00000i\n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(42\\)\n \n 0\n \n 0\n
\n \\(43\\)\n \n 0\n \n 0\n \n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(44\\)\n \n 0\n \n 0\n
\n \\(45\\)\n \n 1.36603\n \n \u2212\n \n 0.366025i\n 1.36603\n \n \u2212\n \n 0.366025i
\n \\(46\\)\n \n 0\n \n 0\n
\n \\(47\\)\n \n 0\n \n 0\n \n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(48\\)\n \n 0\n \n 0\n
\n \\(49\\)\n \n 0\n \n 0\n
\n \\(50\\)\n \n \u22121.00000\n \n \u22121.00000\n
\n \\(51\\)\n \n 0\n \n 0\n
\n \\(52\\)\n \n 0\n \n 0\n
\n \\(53\\)\n \n 0\n \n 0\n \n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n \u22120.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(54\\)\n \n 0\n \n 0\n
\n \\(55\\)\n \n 0\n \n 0\n
\n \\(56\\)\n \n 0\n \n 0\n
\n \\(57\\)\n \n 0\n \n 0\n
\n \\(58\\)\n \n \u22120.366025\n \n +\n \n 1.36603i\n \u22120.366025\n \n +\n \n 1.36603i
\n \\(59\\)\n \n 0\n \n 0\n \n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(60\\)\n \n 0\n \n 0\n
\n \\(61\\)\n \n 0.366025\n \n \u2212\n \n 1.36603i\n 0.366025\n \n \u2212\n \n 1.36603i\n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \\(62\\)\n \n 0\n \n 0\n
\n \\(63\\)\n \n 0\n \n 0\n
\n \\(64\\)\n \n \u22121.00000\n \n \u22121.00000\n
\n \\(65\\)\n \n 0\n \n 0\n
\n \\(66\\)\n \n 0\n \n 0\n
\n \\(67\\)\n \n 0\n \n 0\n \n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n \u22120.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(68\\)\n \n 0.500000\n \n +\n \n 0.866025i\n 0.500000\n \n +\n \n 0.866025i
\n \\(69\\)\n \n 0\n \n 0\n
\n \\(70\\)\n \n 0\n \n 0\n
\n \\(71\\)\n \n 0\n \n 0\n \n 0.707107\n \n \u2212\n \n 0.707107i\n \\(-0.250000\\pi\\)\n
\n \u22120.707107\n \n +\n \n 0.707107i\n \\(0.750000\\pi\\)\n
\n \\(72\\)\n \n \u22120.500000\n \n \u2212\n \n 0.866025i\n \u22120.500000\n \n \u2212\n \n 0.866025i
\n \\(73\\)\n \n \u22120.366025\n \n \u2212\n \n 1.36603i\n \u22120.366025\n \n \u2212\n \n 1.36603i\n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n \\(74\\)\n \n \u22121.36603\n \n +\n \n 0.366025i\n \u22121.36603\n \n +\n \n 0.366025i
\n \\(75\\)\n \n 0\n \n 0\n
\n \\(76\\)\n \n 0\n \n 0\n
\n \\(77\\)\n \n 0\n \n 0\n
\n \\(78\\)\n \n 0\n \n 0\n
\n \\(79\\)\n \n 0\n \n 0\n \n 0.258819\n \n \u2212\n \n 0.965926i\n \\(-0.416667\\pi\\)\n
\n \u22120.258819\n \n +\n \n 0.965926i\n \\(0.583333\\pi\\)\n
\n \\(80\\)\n \n 0.366025\n \n +\n \n 1.36603i\n 0.366025\n \n +\n \n 1.36603i
\n \\(81\\)\n \n 0.500000\n \n \u2212\n \n 0.866025i\n 0.500000\n \n \u2212\n \n 0.866025i
\n \\(82\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i
\n \\(83\\)\n \n 0\n \n 0\n \n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(84\\)\n \n 0\n \n 0\n
\n \\(85\\)\n \n 1.00000\n \n \u2212\n \n 1.00000i\n 1.00000\n \n \u2212\n \n 1.00000i
\n \\(86\\)\n \n 0\n \n 0\n
\n \\(87\\)\n \n 0\n \n 0\n
\n \\(88\\)\n \n 0\n \n 0\n
\n \\(89\\)\n \n 0\n \n 0\n \n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(90\\)\n \n \u22121.00000\n \n +\n \n 1.00000i\n \u22121.00000\n \n +\n \n 1.00000i
\n \\(91\\)\n \n 0\n \n 0\n
\n \\(92\\)\n \n 0\n \n 0\n
\n \\(93\\)\n \n 0\n \n 0\n
\n \\(94\\)\n \n 0\n \n 0\n
\n \\(95\\)\n \n 0\n \n 0\n
\n \\(96\\)\n \n 0\n \n 0\n
\n \\(97\\)\n \n 1.00000\n \n \u2212\n \n 1.00000i\n 1.00000\n \n \u2212\n \n 1.00000i\n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000\n \n \\(0\\)\n
\n \\(98\\)\n \n 0\n \n 0\n
\n \\(99\\)\n \n 0\n \n 0\n
\n \\(100\\)\n \n 0.866025\n \n \u2212\n \n 0.500000i\n 0.866025\n \n \u2212\n \n 0.500000i
\n \\(101\\)\n \n 0\n \n 0\n \n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(102\\)\n \n 0\n \n 0\n
\n \\(103\\)\n \n 0\n \n 0\n \n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(104\\)\n \n 0\n \n 0\n
\n \\(105\\)\n \n 0\n \n 0\n
\n \\(106\\)\n \n 0\n \n 0\n
\n \\(107\\)\n \n 0\n \n 0\n \n \u22120.965926\n \n \u2212\n \n 0.258819i\n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \\(0.0833333\\pi\\)\n
\n \\(108\\)\n \n 0\n \n 0\n
\n \\(109\\)\n \n 1.36603\n \n \u2212\n \n 0.366025i\n 1.36603\n \n \u2212\n \n 0.366025i\n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(110\\)\n \n 0\n \n 0\n
\n \\(111\\)\n \n 0\n \n 0\n
\n \\(112\\)\n \n 0\n \n 0\n
\n \\(113\\)\n \n \u22121.00000\n \n \u2212\n \n 1.00000i\n \u22121.00000\n \n \u2212\n \n 1.00000i\n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(114\\)\n \n 0\n \n 0\n
\n \\(115\\)\n \n 0\n \n 0\n
\n \\(116\\)\n \n \u22120.366025\n \n \u2212\n \n 1.36603i\n \u22120.366025\n \n \u2212\n \n 1.36603i
\n \\(117\\)\n \n 0\n \n 0\n
\n \\(118\\)\n \n 0\n \n 0\n
\n \\(119\\)\n \n 0\n \n 0\n
\n \\(120\\)\n \n 0\n \n 0\n
\n \\(121\\)\n \n 0.866025\n \n \u2212\n \n 0.500000i\n 0.866025\n \n \u2212\n \n 0.500000i
\n \\(122\\)\n \n 0.366025\n \n +\n \n 1.36603i\n 0.366025\n \n +\n \n 1.36603i
\n \\(123\\)\n \n 0\n \n 0\n
\n \\(124\\)\n \n 0\n \n 0\n
\n \\(125\\)\n \n 0\n \n 0\n
\n \\(126\\)\n \n 0\n \n 0\n
\n \\(127\\)\n \n 0\n \n 0\n \n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(128\\)\n \n 0.866025\n \n \u2212\n \n 0.500000i\n 0.866025\n \n \u2212\n \n 0.500000i
\n \\(129\\)\n \n 0\n \n 0\n
\n \\(130\\)\n \n 0\n \n 0\n
\n \\(131\\)\n \n 0\n \n 0\n \n \u22120.965926\n \n \u2212\n \n 0.258819i\n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \\(0.0833333\\pi\\)\n
\n \\(132\\)\n \n 0\n \n 0\n
\n \\(133\\)\n \n 0\n \n 0\n
\n \\(134\\)\n \n 0\n \n 0\n
\n \\(135\\)\n \n 0\n \n 0\n
\n \\(136\\)\n \n \u22120.866025\n \n \u2212\n \n 0.500000i\n \u22120.866025\n \n \u2212\n \n 0.500000i
\n \\(137\\)\n \n 0\n \n 0\n \n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(138\\)\n \n 0\n \n 0\n
\n \\(139\\)\n \n 0\n \n 0\n \n 0.707107\n \n \u2212\n \n 0.707107i\n \\(-0.250000\\pi\\)\n
\n \u22120.707107\n \n +\n \n 0.707107i\n \\(0.750000\\pi\\)\n
\n \\(140\\)\n \n 0\n \n 0\n
\n \\(141\\)\n \n 0\n \n 0\n
\n \\(142\\)\n \n 0\n \n 0\n
\n \\(143\\)\n \n 0\n \n 0\n
\n \\(144\\)\n \n 0.866025\n \n +\n \n 0.500000i\n 0.866025\n \n +\n \n 0.500000i
\n \\(145\\)\n \n \u22121.73205\n \n +\n \n 1.00000i\n \u22121.73205\n \n +\n \n 1.00000i
\n \\(146\\)\n \n 1.00000\n \n +\n \n 1.00000i\n 1.00000\n \n +\n \n 1.00000i
\n \\(147\\)\n \n 0\n \n 0\n
\n \\(148\\)\n \n 1.00000\n \n \u2212\n \n 1.00000i\n 1.00000\n \n \u2212\n \n 1.00000i
\n \\(149\\)\n \n \u22121.00000\n \n \u2212\n \n 1.73205i\n \u22121.00000\n \n \u2212\n \n 1.73205i\n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n \\(150\\)\n \n 0\n \n 0\n
\n \\(151\\)\n \n 0\n \n 0\n \n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(152\\)\n \n 0\n \n 0\n
\n \\(153\\)\n \n \u2212\n \n 1.00000i\n \u2212\n \n 1.00000i
\n \\(154\\)\n \n 0\n \n 0\n
\n \\(155\\)\n \n 0\n \n 0\n
\n \\(156\\)\n \n 0\n \n 0\n
\n \\(157\\)\n \n 1.00000\n \n \u2212\n \n 1.73205i\n 1.00000\n \n \u2212\n \n 1.73205i\n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n \\(158\\)\n \n 0\n \n 0\n
\n \\(159\\)\n \n 0\n \n 0\n
\n \\(160\\)\n \n \u22121.00000\n \n \u2212\n \n 1.00000i\n \u22121.00000\n \n \u2212\n \n 1.00000i
\n \\(161\\)\n \n 0\n \n 0\n
\n \\(162\\)\n \n 1.00000i\n 1.00000i
\n \\(163\\)\n \n 0\n \n 0\n \n 0.258819\n \n \u2212\n \n 0.965926i\n \\(-0.416667\\pi\\)\n
\n \u22120.258819\n \n +\n \n 0.965926i\n \\(0.583333\\pi\\)\n
\n \\(164\\)\n \n \u22121.36603\n \n +\n \n 0.366025i\n \u22121.36603\n \n +\n \n 0.366025i
\n \\(165\\)\n \n 0\n \n 0\n
\n \\(166\\)\n \n 0\n \n 0\n
\n \\(167\\)\n \n 0\n \n 0\n \n 0.707107\n \n \u2212\n \n 0.707107i\n \\(-0.250000\\pi\\)\n
\n \u22120.707107\n \n +\n \n 0.707107i\n \\(0.750000\\pi\\)\n
\n \\(168\\)\n \n 0\n \n 0\n
\n \\(169\\)\n \n \u22121.00000\n \n \u22121.00000\n
\n \\(170\\)\n \n \u22120.366025\n \n +\n \n 1.36603i\n \u22120.366025\n \n +\n \n 1.36603i
\n \\(171\\)\n \n 0\n \n 0\n
\n \\(172\\)\n \n 0\n \n 0\n
\n \\(173\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i\n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(174\\)\n \n 0\n \n 0\n
\n \\(175\\)\n \n 0\n \n 0\n
\n \\(176\\)\n \n 0\n \n 0\n
\n \\(177\\)\n \n 0\n \n 0\n
\n \\(178\\)\n \n 0\n \n 0\n
\n \\(179\\)\n \n 0\n \n 0\n \n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(180\\)\n \n 0.366025\n \n \u2212\n \n 1.36603i\n 0.366025\n \n \u2212\n \n 1.36603i
\n \\(181\\)\n \n 1.00000\n \n +\n \n 1.00000i\n 1.00000\n \n +\n \n 1.00000i\n 1.00000\n \n \\(0\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(182\\)\n \n 0\n \n 0\n
\n \\(183\\)\n \n 0\n \n 0\n
\n \\(184\\)\n \n 0\n \n 0\n
\n \\(185\\)\n \n \u22121.73205\n \n \u2212\n \n 1.00000i\n \u22121.73205\n \n \u2212\n \n 1.00000i
\n \\(186\\)\n \n 0\n \n 0\n
\n \\(187\\)\n \n 0\n \n 0\n
\n \\(188\\)\n \n 0\n \n 0\n
\n \\(189\\)\n \n 0\n \n 0\n
\n \\(190\\)\n \n 0\n \n 0\n
\n \\(191\\)\n \n 0\n \n 0\n \n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(192\\)\n \n 0\n \n 0\n
\n \\(193\\)\n \n \u22121.36603\n \n +\n \n 0.366025i\n \u22121.36603\n \n +\n \n 0.366025i\n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n \u22120.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(194\\)\n \n \u22120.366025\n \n +\n \n 1.36603i\n \u22120.366025\n \n +\n \n 1.36603i
\n \\(195\\)\n \n 0\n \n 0\n
\n \\(196\\)\n \n 0\n \n 0\n
\n \\(197\\)\n \n 1.00000\n \n +\n \n 1.00000i\n 1.00000\n \n +\n \n 1.00000i\n 1.00000\n \n \\(0\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(198\\)\n \n 0\n \n 0\n
\n \\(199\\)\n \n 0\n \n 0\n \n \u22120.258819\n \n \u2212\n \n 0.965926i\n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \\(0.416667\\pi\\)\n
\n \\(200\\)\n \n \u22120.500000\n \n +\n \n 0.866025i\n \u22120.500000\n \n +\n \n 0.866025i
\n \\(201\\)\n \n 0\n \n 0\n
\n \\(202\\)\n \n 0\n \n 0\n
\n \\(203\\)\n \n 0\n \n 0\n
\n \\(204\\)\n \n 0\n \n 0\n
\n \\(205\\)\n \n 1.00000\n \n +\n \n 1.73205i\n 1.00000\n \n +\n \n 1.73205i
\n \\(206\\)\n \n 0\n \n 0\n
\n \\(207\\)\n \n 0\n \n 0\n
\n \\(208\\)\n \n 0\n \n 0\n
\n \\(209\\)\n \n 0\n \n 0\n
\n \\(210\\)\n \n 0\n \n 0\n
\n \\(211\\)\n \n 0\n \n 0\n \n \u22120.707107\n \n \u2212\n \n 0.707107i\n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \\(0.250000\\pi\\)\n
\n \\(212\\)\n \n 0\n \n 0\n
\n \\(213\\)\n \n 0\n \n 0\n
\n \\(214\\)\n \n 0\n \n 0\n
\n \\(215\\)\n \n 0\n \n 0\n
\n \\(216\\)\n \n 0\n \n 0\n
\n \\(217\\)\n \n 0\n \n 0\n
\n \\(218\\)\n \n \u22121.00000\n \n +\n \n 1.00000i\n \u22121.00000\n \n +\n \n 1.00000i
\n \\(219\\)\n \n 0\n \n 0\n
\n \\(220\\)\n \n 0\n \n 0\n
\n \\(221\\)\n \n 0\n \n 0\n
\n \\(222\\)\n \n 0\n \n 0\n
\n \\(223\\)\n \n 0\n \n 0\n \n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(224\\)\n \n 0\n \n 0\n
\n \\(225\\)\n \n \u22121.00000\n \n \u22121.00000\n
\n \\(226\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i
\n \\(227\\)\n \n 0\n \n 0\n \n 0.965926\n \n \u2212\n \n 0.258819i\n \\(-0.0833333\\pi\\)\n
\n \u22120.965926\n \n +\n \n 0.258819i\n \\(0.916667\\pi\\)\n
\n \\(228\\)\n \n 0\n \n 0\n
\n \\(229\\)\n \n \u22121.73205\n \n +\n \n 1.00000i\n \u22121.73205\n \n +\n \n 1.00000i\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(230\\)\n \n 0\n \n 0\n
\n \\(231\\)\n \n 0\n \n 0\n
\n \\(232\\)\n \n 1.00000\n \n +\n \n 1.00000i\n 1.00000\n \n +\n \n 1.00000i
\n \\(233\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i\n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(234\\)\n \n 0\n \n 0\n
\n \\(235\\)\n \n 0\n \n 0\n
\n \\(236\\)\n \n 0\n \n 0\n
\n \\(237\\)\n \n 0\n \n 0\n
\n \\(238\\)\n \n 0\n \n 0\n
\n \\(239\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(240\\)\n \n 0\n \n 0\n
\n \\(241\\)\n \n \u22120.366025\n \n \u2212\n \n 1.36603i\n \u22120.366025\n \n \u2212\n \n 1.36603i\n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n \\(242\\)\n \n \u22120.500000\n \n +\n \n 0.866025i\n \u22120.500000\n \n +\n \n 0.866025i
\n \\(243\\)\n \n 0\n \n 0\n
\n \\(244\\)\n \n \u22121.00000\n \n \u2212\n \n 1.00000i\n \u22121.00000\n \n \u2212\n \n 1.00000i
\n \\(245\\)\n \n 0\n \n 0\n
\n \\(246\\)\n \n 0\n \n 0\n
\n \\(247\\)\n \n 0\n \n 0\n
\n \\(248\\)\n \n 0\n \n 0\n
\n \\(249\\)\n \n 0\n \n 0\n
\n \\(250\\)\n \n 0\n \n 0\n
\n \\(251\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(252\\)\n \n 0\n \n 0\n
\n \\(253\\)\n \n 0\n \n 0\n
\n \\(254\\)\n \n 0\n \n 0\n
\n \\(255\\)\n \n 0\n \n 0\n
\n \\(256\\)\n \n \u22120.500000\n \n +\n \n 0.866025i\n \u22120.500000\n \n +\n \n 0.866025i
\n \\(257\\)\n \n 1.73205\n \n \u2212\n \n 1.00000i\n 1.73205\n \n \u2212\n \n 1.00000i\n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \\(258\\)\n \n 0\n \n 0\n
\n \\(259\\)\n \n 0\n \n 0\n
\n \\(260\\)\n \n 0\n \n 0\n
\n \\(261\\)\n \n \u22120.366025\n \n +\n \n 1.36603i\n \u22120.366025\n \n +\n \n 1.36603i
\n \\(262\\)\n \n 0\n \n 0\n
\n \\(263\\)\n \n 0\n \n 0\n \n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(264\\)\n \n 0\n \n 0\n
\n \\(265\\)\n \n 0\n \n 0\n
\n \\(266\\)\n \n 0\n \n 0\n
\n \\(267\\)\n \n 0\n \n 0\n
\n \\(268\\)\n \n 0\n \n 0\n
\n \\(269\\)\n \n 0.366025\n \n +\n \n 1.36603i\n 0.366025\n \n +\n \n 1.36603i\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \u22120.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(270\\)\n \n 0\n \n 0\n
\n \\(271\\)\n \n 0\n \n 0\n \n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(272\\)\n \n 1.00000\n \n 1.00000\n
\n \\(273\\)\n \n 0\n \n 0\n
\n \\(274\\)\n \n 0\n \n 0\n
\n \\(275\\)\n \n 0\n \n 0\n
\n \\(276\\)\n \n 0\n \n 0\n
\n \\(277\\)\n \n 0.366025\n \n +\n \n 1.36603i\n 0.366025\n \n +\n \n 1.36603i\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \u22120.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(278\\)\n \n 0\n \n 0\n
\n \\(279\\)\n \n 0\n \n 0\n
\n \\(280\\)\n \n 0\n \n 0\n
\n \\(281\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(282\\)\n \n 0\n \n 0\n
\n \\(283\\)\n \n 0\n \n 0\n \n 0.965926\n \n \u2212\n \n 0.258819i\n \\(-0.0833333\\pi\\)\n
\n \u22120.965926\n \n +\n \n 0.258819i\n \\(0.916667\\pi\\)\n
\n \\(284\\)\n \n 0\n \n 0\n
\n \\(285\\)\n \n 0\n \n 0\n
\n \\(286\\)\n \n 0\n \n 0\n
\n \\(287\\)\n \n 0\n \n 0\n
\n \\(288\\)\n \n \u22121.00000\n \n \u22121.00000\n
\n \\(289\\)\n \n \u22120.500000\n \n \u2212\n \n 0.866025i\n \u22120.500000\n \n \u2212\n \n 0.866025i
\n \\(290\\)\n \n 1.00000\n \n \u2212\n \n 1.73205i\n 1.00000\n \n \u2212\n \n 1.73205i
\n \\(291\\)\n \n 0\n \n 0\n
\n \\(292\\)\n \n \u22121.36603\n \n \u2212\n \n 0.366025i\n \u22121.36603\n \n \u2212\n \n 0.366025i
\n \\(293\\)\n \n 2.00000\n \n 2.00000\n \n 1.00000\n \n \\(0\\)\n
\n 1.00000\n \n \\(0\\)\n
\n \\(294\\)\n \n 0\n \n 0\n
\n \\(295\\)\n \n 0\n \n 0\n
\n \\(296\\)\n \n \u22120.366025\n \n +\n \n 1.36603i\n \u22120.366025\n \n +\n \n 1.36603i
\n \\(297\\)\n \n 0\n \n 0\n
\n \\(298\\)\n \n 1.73205\n \n +\n \n 1.00000i\n 1.73205\n \n +\n \n 1.00000i
\n \\(299\\)\n \n 0\n \n 0\n
\n \\(300\\)\n \n 0\n \n 0\n
\n \\(301\\)\n \n 0\n \n 0\n
\n \\(302\\)\n \n 0\n \n 0\n
\n \\(303\\)\n \n 0\n \n 0\n
\n \\(304\\)\n \n 0\n \n 0\n
\n \\(305\\)\n \n \u22121.00000\n \n +\n \n 1.73205i\n \u22121.00000\n \n +\n \n 1.73205i
\n \\(306\\)\n \n 0.500000\n \n +\n \n 0.866025i\n 0.500000\n \n +\n \n 0.866025i
\n \\(307\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(308\\)\n \n 0\n \n 0\n
\n \\(309\\)\n \n 0\n \n 0\n
\n \\(310\\)\n \n 0\n \n 0\n
\n \\(311\\)\n \n 0\n \n 0\n \n \u22120.258819\n \n \u2212\n \n 0.965926i\n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \\(0.416667\\pi\\)\n
\n \\(312\\)\n \n 0\n \n 0\n
\n \\(313\\)\n \n \u22120.366025\n \n +\n \n 1.36603i\n \u22120.366025\n \n +\n \n 1.36603i\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(314\\)\n \n 2.00000i\n 2.00000i
\n \\(315\\)\n \n 0\n \n 0\n
\n \\(316\\)\n \n 0\n \n 0\n
\n \\(317\\)\n \n 0.366025\n \n \u2212\n \n 1.36603i\n 0.366025\n \n \u2212\n \n 1.36603i\n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \\(318\\)\n \n 0\n \n 0\n
\n \\(319\\)\n \n 0\n \n 0\n
\n \\(320\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i
\n \\(321\\)\n \n 0\n \n 0\n
\n \\(322\\)\n \n 0\n \n 0\n
\n \\(323\\)\n \n 0\n \n 0\n
\n \\(324\\)\n \n \u22120.500000\n \n \u2212\n \n 0.866025i\n \u22120.500000\n \n \u2212\n \n 0.866025i
\n \\(325\\)\n \n 0\n \n 0\n
\n \\(326\\)\n \n 0\n \n 0\n
\n \\(327\\)\n \n 0\n \n 0\n
\n \\(328\\)\n \n 1.00000\n \n \u2212\n \n 1.00000i\n 1.00000\n \n \u2212\n \n 1.00000i
\n \\(329\\)\n \n 0\n \n 0\n
\n \\(330\\)\n \n 0\n \n 0\n
\n \\(331\\)\n \n 0\n \n 0\n \n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(332\\)\n \n 0\n \n 0\n
\n \\(333\\)\n \n \u22121.36603\n \n +\n \n 0.366025i\n \u22121.36603\n \n +\n \n 0.366025i
\n \\(334\\)\n \n 0\n \n 0\n
\n \\(335\\)\n \n 0\n \n 0\n
\n \\(336\\)\n \n 0\n \n 0\n
\n \\(337\\)\n \n 1.00000\n \n \u2212\n \n 1.00000i\n 1.00000\n \n \u2212\n \n 1.00000i\n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000\n \n \\(0\\)\n
\n \\(338\\)\n \n 0.866025\n \n \u2212\n \n 0.500000i\n 0.866025\n \n \u2212\n \n 0.500000i
\n \\(339\\)\n \n 0\n \n 0\n
\n \\(340\\)\n \n \u22120.366025\n \n \u2212\n \n 1.36603i\n \u22120.366025\n \n \u2212\n \n 1.36603i
\n \\(341\\)\n \n 0\n \n 0\n
\n \\(342\\)\n \n 0\n \n 0\n
\n \\(343\\)\n \n 0\n \n 0\n
\n \\(344\\)\n \n 0\n \n 0\n
\n \\(345\\)\n \n 0\n \n 0\n
\n \\(346\\)\n \n \u22121.36603\n \n +\n \n 0.366025i\n \u22121.36603\n \n +\n \n 0.366025i
\n \\(347\\)\n \n 0\n \n 0\n \n 0.965926\n \n \u2212\n \n 0.258819i\n \\(-0.0833333\\pi\\)\n
\n \u22120.965926\n \n +\n \n 0.258819i\n \\(0.916667\\pi\\)\n
\n \\(348\\)\n \n 0\n \n 0\n
\n \\(349\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(350\\)\n \n 0\n \n 0\n
\n \\(351\\)\n \n 0\n \n 0\n
\n \\(352\\)\n \n 0\n \n 0\n
\n \\(353\\)\n \n \u22121.00000\n \n +\n \n 1.73205i\n \u22121.00000\n \n +\n \n 1.73205i\n \u22120.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \u22120.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(354\\)\n \n 0\n \n 0\n
\n \\(355\\)\n \n 0\n \n 0\n
\n \\(356\\)\n \n 0\n \n 0\n
\n \\(357\\)\n \n 0\n \n 0\n
\n \\(358\\)\n \n 0\n \n 0\n
\n \\(359\\)\n \n 0\n \n 0\n \n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(360\\)\n \n 0.366025\n \n +\n \n 1.36603i\n 0.366025\n \n +\n \n 1.36603i
\n \\(361\\)\n \n 0.500000\n \n \u2212\n \n 0.866025i\n 0.500000\n \n \u2212\n \n 0.866025i
\n \\(362\\)\n \n \u22121.36603\n \n \u2212\n \n 0.366025i\n \u22121.36603\n \n \u2212\n \n 0.366025i
\n \\(363\\)\n \n 0\n \n 0\n
\n \\(364\\)\n \n 0\n \n 0\n
\n \\(365\\)\n \n 2.00000i\n 2.00000i
\n \\(366\\)\n \n 0\n \n 0\n
\n \\(367\\)\n \n 0\n \n 0\n \n 0.965926\n \n \u2212\n \n 0.258819i\n \\(-0.0833333\\pi\\)\n
\n \u22120.965926\n \n +\n \n 0.258819i\n \\(0.916667\\pi\\)\n
\n \\(368\\)\n \n 0\n \n 0\n
\n \\(369\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i
\n \\(370\\)\n \n 2.00000\n \n 2.00000\n
\n \\(371\\)\n \n 0\n \n 0\n
\n \\(372\\)\n \n 0\n \n 0\n
\n \\(373\\)\n \n 0\n \n 0\n \n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(374\\)\n \n 0\n \n 0\n
\n \\(375\\)\n \n 0\n \n 0\n
\n \\(376\\)\n \n 0\n \n 0\n
\n \\(377\\)\n \n 0\n \n 0\n
\n \\(378\\)\n \n 0\n \n 0\n
\n \\(379\\)\n \n 0\n \n 0\n \n 0.707107\n \n \u2212\n \n 0.707107i\n \\(-0.250000\\pi\\)\n
\n \u22120.707107\n \n +\n \n 0.707107i\n \\(0.750000\\pi\\)\n
\n \\(380\\)\n \n 0\n \n 0\n
\n \\(381\\)\n \n 0\n \n 0\n
\n \\(382\\)\n \n 0\n \n 0\n
\n \\(383\\)\n \n 0\n \n 0\n \n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(384\\)\n \n 0\n \n 0\n
\n \\(385\\)\n \n 0\n \n 0\n
\n \\(386\\)\n \n 1.00000\n \n \u2212\n \n 1.00000i\n 1.00000\n \n \u2212\n \n 1.00000i
\n \\(387\\)\n \n 0\n \n 0\n
\n \\(388\\)\n \n \u22120.366025\n \n \u2212\n \n 1.36603i\n \u22120.366025\n \n \u2212\n \n 1.36603i
\n \\(389\\)\n \n \u22121.73205\n \n \u2212\n \n 1.00000i\n \u22121.73205\n \n \u2212\n \n 1.00000i\n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n \\(390\\)\n \n 0\n \n 0\n
\n \\(391\\)\n \n 0\n \n 0\n
\n \\(392\\)\n \n 0\n \n 0\n
\n \\(393\\)\n \n 0\n \n 0\n
\n \\(394\\)\n \n \u22121.36603\n \n \u2212\n \n 0.366025i\n \u22121.36603\n \n \u2212\n \n 0.366025i
\n \\(395\\)\n \n 0\n \n 0\n
\n \\(396\\)\n \n 0\n \n 0\n
\n \\(397\\)\n \n 0.366025\n \n \u2212\n \n 1.36603i\n 0.366025\n \n \u2212\n \n 1.36603i\n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \\(398\\)\n \n 0\n \n 0\n
\n \\(399\\)\n \n 0\n \n 0\n
\n \\(400\\)\n \n \u2212\n \n 1.00000i\n \u2212\n \n 1.00000i
\n \\(401\\)\n \n 0.366025\n \n \u2212\n \n 1.36603i\n 0.366025\n \n \u2212\n \n 1.36603i\n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \\(402\\)\n \n 0\n \n 0\n
\n \\(403\\)\n \n 0\n \n 0\n
\n \\(404\\)\n \n 0\n \n 0\n
\n \\(405\\)\n \n \u22121.00000\n \n +\n \n 1.00000i\n \u22121.00000\n \n +\n \n 1.00000i
\n \\(406\\)\n \n 0\n \n 0\n
\n \\(407\\)\n \n 0\n \n 0\n
\n \\(408\\)\n \n 0\n \n 0\n
\n \\(409\\)\n \n \u22121.00000\n \n +\n \n 1.73205i\n \u22121.00000\n \n +\n \n 1.73205i\n \u22120.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \u22120.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(410\\)\n \n \u22121.73205\n \n \u2212\n \n 1.00000i\n \u22121.73205\n \n \u2212\n \n 1.00000i
\n \\(411\\)\n \n 0\n \n 0\n
\n \\(412\\)\n \n 0\n \n 0\n
\n \\(413\\)\n \n 0\n \n 0\n
\n \\(414\\)\n \n 0\n \n 0\n
\n \\(415\\)\n \n 0\n \n 0\n
\n \\(416\\)\n \n 0\n \n 0\n
\n \\(417\\)\n \n 0\n \n 0\n
\n \\(418\\)\n \n 0\n \n 0\n
\n \\(419\\)\n \n 0\n \n 0\n \n \u22120.707107\n \n \u2212\n \n 0.707107i\n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \\(0.250000\\pi\\)\n
\n \\(420\\)\n \n 0\n \n 0\n
\n \\(421\\)\n \n 0\n \n 0\n \n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(422\\)\n \n 0\n \n 0\n
\n \\(423\\)\n \n 0\n \n 0\n
\n \\(424\\)\n \n 0\n \n 0\n
\n \\(425\\)\n \n \u22120.866025\n \n +\n \n 0.500000i\n \u22120.866025\n \n +\n \n 0.500000i
\n \\(426\\)\n \n 0\n \n 0\n
\n \\(427\\)\n \n 0\n \n 0\n
\n \\(428\\)\n \n 0\n \n 0\n
\n \\(429\\)\n \n 0\n \n 0\n
\n \\(430\\)\n \n 0\n \n 0\n
\n \\(431\\)\n \n 0\n \n 0\n \n 0.965926\n \n \u2212\n \n 0.258819i\n \\(-0.0833333\\pi\\)\n
\n \u22120.965926\n \n +\n \n 0.258819i\n \\(0.916667\\pi\\)\n
\n \\(432\\)\n \n 0\n \n 0\n
\n \\(433\\)\n \n 2.00000i\n 2.00000i\n 1.00000i\n \\(0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(434\\)\n \n 0\n \n 0\n
\n \\(435\\)\n \n 0\n \n 0\n
\n \\(436\\)\n \n 0.366025\n \n \u2212\n \n 1.36603i\n 0.366025\n \n \u2212\n \n 1.36603i
\n \\(437\\)\n \n 0\n \n 0\n
\n \\(438\\)\n \n 0\n \n 0\n
\n \\(439\\)\n \n 0\n \n 0\n \n \u22120.965926\n \n \u2212\n \n 0.258819i\n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \\(0.0833333\\pi\\)\n
\n \\(440\\)\n \n 0\n \n 0\n
\n \\(441\\)\n \n 0\n \n 0\n
\n \\(442\\)\n \n 0\n \n 0\n
\n \\(443\\)\n \n 0\n \n 0\n \n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(444\\)\n \n 0\n \n 0\n
\n \\(445\\)\n \n 0\n \n 0\n
\n \\(446\\)\n \n 0\n \n 0\n
\n \\(447\\)\n \n 0\n \n 0\n
\n \\(448\\)\n \n 0\n \n 0\n
\n \\(449\\)\n \n \u22121.00000\n \n \u2212\n \n 1.00000i\n \u22121.00000\n \n \u2212\n \n 1.00000i\n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(450\\)\n \n 0.866025\n \n \u2212\n \n 0.500000i\n 0.866025\n \n \u2212\n \n 0.500000i
\n \\(451\\)\n \n 0\n \n 0\n
\n \\(452\\)\n \n \u22121.36603\n \n +\n \n 0.366025i\n \u22121.36603\n \n +\n \n 0.366025i
\n \\(453\\)\n \n 0\n \n 0\n
\n \\(454\\)\n \n 0\n \n 0\n
\n \\(455\\)\n \n 0\n \n 0\n
\n \\(456\\)\n \n 0\n \n 0\n
\n \\(457\\)\n \n \u22121.73205\n \n +\n \n 1.00000i\n \u22121.73205\n \n +\n \n 1.00000i\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(458\\)\n \n 1.00000\n \n \u2212\n \n 1.73205i\n 1.00000\n \n \u2212\n \n 1.73205i
\n \\(459\\)\n \n 0\n \n 0\n
\n \\(460\\)\n \n 0\n \n 0\n
\n \\(461\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(462\\)\n \n 0\n \n 0\n
\n \\(463\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(464\\)\n \n \u22121.36603\n \n \u2212\n \n 0.366025i\n \u22121.36603\n \n \u2212\n \n 0.366025i
\n \\(465\\)\n \n 0\n \n 0\n
\n \\(466\\)\n \n \u22121.36603\n \n +\n \n 0.366025i\n \u22121.36603\n \n +\n \n 0.366025i
\n \\(467\\)\n \n 0\n \n 0\n \n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(468\\)\n \n 0\n \n 0\n
\n \\(469\\)\n \n 0\n \n 0\n
\n \\(470\\)\n \n 0\n \n 0\n
\n \\(471\\)\n \n 0\n \n 0\n
\n \\(472\\)\n \n 0\n \n 0\n
\n \\(473\\)\n \n 0\n \n 0\n
\n \\(474\\)\n \n 0\n \n 0\n
\n \\(475\\)\n \n 0\n \n 0\n
\n \\(476\\)\n \n 0\n \n 0\n
\n \\(477\\)\n \n 0\n \n 0\n
\n \\(478\\)\n \n 0\n \n 0\n
\n \\(479\\)\n \n 0\n \n 0\n \n \u22120.258819\n \n \u2212\n \n 0.965926i\n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \\(0.416667\\pi\\)\n
\n \\(480\\)\n \n 0\n \n 0\n
\n \\(481\\)\n \n 0\n \n 0\n
\n \\(482\\)\n \n 1.00000\n \n +\n \n 1.00000i\n 1.00000\n \n +\n \n 1.00000i
\n \\(483\\)\n \n 0\n \n 0\n
\n \\(484\\)\n \n \u2212\n \n 1.00000i\n \u2212\n \n 1.00000i
\n \\(485\\)\n \n \u22121.73205\n \n +\n \n 1.00000i\n \u22121.73205\n \n +\n \n 1.00000i
\n \\(486\\)\n \n 0\n \n 0\n
\n \\(487\\)\n \n 0\n \n 0\n \n 0.965926\n \n \u2212\n \n 0.258819i\n \\(-0.0833333\\pi\\)\n
\n \u22120.965926\n \n +\n \n 0.258819i\n \\(0.916667\\pi\\)\n
\n \\(488\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i
\n \\(489\\)\n \n 0\n \n 0\n
\n \\(490\\)\n \n 0\n \n 0\n
\n \\(491\\)\n \n 0\n \n 0\n \n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(492\\)\n \n 0\n \n 0\n
\n \\(493\\)\n \n 0.366025\n \n +\n \n 1.36603i\n 0.366025\n \n +\n \n 1.36603i
\n \\(494\\)\n \n 0\n \n 0\n
\n \\(495\\)\n \n 0\n \n 0\n
\n \\(496\\)\n \n 0\n \n 0\n
\n \\(497\\)\n \n 0\n \n 0\n
\n \\(498\\)\n \n 0\n \n 0\n
\n \\(499\\)\n \n 0\n \n 0\n \n 0.258819\n \n \u2212\n \n 0.965926i\n \\(-0.416667\\pi\\)\n
\n \u22120.258819\n \n +\n \n 0.965926i\n \\(0.583333\\pi\\)\n
\n \\(500\\)\n \n 0\n \n 0\n
\n \\(501\\)\n \n 0\n \n 0\n
\n \\(502\\)\n \n 0\n \n 0\n
\n \\(503\\)\n \n 0\n \n 0\n \n \u22120.707107\n \n \u2212\n \n 0.707107i\n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \\(0.250000\\pi\\)\n
\n \\(504\\)\n \n 0\n \n 0\n
\n \\(505\\)\n \n 0\n \n 0\n
\n \\(506\\)\n \n 0\n \n 0\n
\n \\(507\\)\n \n 0\n \n 0\n
\n \\(508\\)\n \n 0\n \n 0\n
\n \\(509\\)\n \n \u22121.00000\n \n \u2212\n \n 1.73205i\n \u22121.00000\n \n \u2212\n \n 1.73205i\n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n \\(510\\)\n \n 0\n \n 0\n
\n \\(511\\)\n \n 0\n \n 0\n
\n \\(512\\)\n \n \u2212\n \n 1.00000i\n \u2212\n \n 1.00000i
\n \\(513\\)\n \n 0\n \n 0\n
\n \\(514\\)\n \n \u22121.00000\n \n +\n \n 1.73205i\n \u22121.00000\n \n +\n \n 1.73205i
\n \\(515\\)\n \n 0\n \n 0\n
\n \\(516\\)\n \n 0\n \n 0\n
\n \\(517\\)\n \n 0\n \n 0\n
\n \\(518\\)\n \n 0\n \n 0\n
\n \\(519\\)\n \n 0\n \n 0\n
\n \\(520\\)\n \n 0\n \n 0\n
\n \\(521\\)\n \n 1.36603\n \n \u2212\n \n 0.366025i\n 1.36603\n \n \u2212\n \n 0.366025i\n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(522\\)\n \n \u22120.366025\n \n \u2212\n \n 1.36603i\n \u22120.366025\n \n \u2212\n \n 1.36603i
\n \\(523\\)\n \n 0\n \n 0\n \n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(524\\)\n \n 0\n \n 0\n
\n \\(525\\)\n \n 0\n \n 0\n
\n \\(526\\)\n \n 0\n \n 0\n
\n \\(527\\)\n \n 0\n \n 0\n
\n \\(528\\)\n \n 0\n \n 0\n
\n \\(529\\)\n \n \u22120.866025\n \n \u2212\n \n 0.500000i\n \u22120.866025\n \n \u2212\n \n 0.500000i
\n \\(530\\)\n \n 0\n \n 0\n
\n \\(531\\)\n \n 0\n \n 0\n
\n \\(532\\)\n \n 0\n \n 0\n
\n \\(533\\)\n \n 0\n \n 0\n
\n \\(534\\)\n \n 0\n \n 0\n
\n \\(535\\)\n \n 0\n \n 0\n
\n \\(536\\)\n \n 0\n \n 0\n
\n \\(537\\)\n \n 0\n \n 0\n
\n \\(538\\)\n \n \u22121.00000\n \n \u2212\n \n 1.00000i\n \u22121.00000\n \n \u2212\n \n 1.00000i
\n \\(539\\)\n \n 0\n \n 0\n
\n \\(540\\)\n \n 0\n \n 0\n
\n \\(541\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i\n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(542\\)\n \n 0\n \n 0\n
\n \\(543\\)\n \n 0\n \n 0\n
\n \\(544\\)\n \n \u22120.866025\n \n +\n \n 0.500000i\n \u22120.866025\n \n +\n \n 0.500000i
\n \\(545\\)\n \n \u22122.00000\n \n \u22122.00000\n
\n \\(546\\)\n \n 0\n \n 0\n
\n \\(547\\)\n \n 0\n \n 0\n \n 0.707107\n \n \u2212\n \n 0.707107i\n \\(-0.250000\\pi\\)\n
\n \u22120.707107\n \n +\n \n 0.707107i\n \\(0.750000\\pi\\)\n
\n \\(548\\)\n \n 0\n \n 0\n
\n \\(549\\)\n \n 0.366025\n \n +\n \n 1.36603i\n 0.366025\n \n +\n \n 1.36603i
\n \\(550\\)\n \n 0\n \n 0\n
\n \\(551\\)\n \n 0\n \n 0\n
\n \\(552\\)\n \n 0\n \n 0\n
\n \\(553\\)\n \n 0\n \n 0\n
\n \\(554\\)\n \n \u22121.00000\n \n \u2212\n \n 1.00000i\n \u22121.00000\n \n \u2212\n \n 1.00000i
\n \\(555\\)\n \n 0\n \n 0\n
\n \\(556\\)\n \n 0\n \n 0\n
\n \\(557\\)\n \n 0\n \n 0\n \n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(558\\)\n \n 0\n \n 0\n
\n \\(559\\)\n \n 0\n \n 0\n
\n \\(560\\)\n \n 0\n \n 0\n
\n \\(561\\)\n \n 0\n \n 0\n
\n \\(562\\)\n \n 0\n \n 0\n
\n \\(563\\)\n \n 0\n \n 0\n \n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(564\\)\n \n 0\n \n 0\n
\n \\(565\\)\n \n 1.00000\n \n +\n \n 1.73205i\n 1.00000\n \n +\n \n 1.73205i
\n \\(566\\)\n \n 0\n \n 0\n
\n \\(567\\)\n \n 0\n \n 0\n
\n \\(568\\)\n \n 0\n \n 0\n
\n \\(569\\)\n \n 0\n \n 0\n \n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(570\\)\n \n 0\n \n 0\n
\n \\(571\\)\n \n 0\n \n 0\n \n 0.965926\n \n \u2212\n \n 0.258819i\n \\(-0.0833333\\pi\\)\n
\n \u22120.965926\n \n +\n \n 0.258819i\n \\(0.916667\\pi\\)\n
\n \\(572\\)\n \n 0\n \n 0\n
\n \\(573\\)\n \n 0\n \n 0\n
\n \\(574\\)\n \n 0\n \n 0\n
\n \\(575\\)\n \n 0\n \n 0\n
\n \\(576\\)\n \n 0.866025\n \n \u2212\n \n 0.500000i\n 0.866025\n \n \u2212\n \n 0.500000i
\n \\(577\\)\n \n 0\n \n 0\n \n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(578\\)\n \n 0.866025\n \n +\n \n 0.500000i\n 0.866025\n \n +\n \n 0.500000i
\n \\(579\\)\n \n 0\n \n 0\n
\n \\(580\\)\n \n 2.00000i\n 2.00000i
\n \\(581\\)\n \n 0\n \n 0\n
\n \\(582\\)\n \n 0\n \n 0\n
\n \\(583\\)\n \n 0\n \n 0\n
\n \\(584\\)\n \n 1.36603\n \n \u2212\n \n 0.366025i\n 1.36603\n \n \u2212\n \n 0.366025i
\n \\(585\\)\n \n 0\n \n 0\n
\n \\(586\\)\n \n \u22121.73205\n \n +\n \n 1.00000i\n \u22121.73205\n \n +\n \n 1.00000i
\n \\(587\\)\n \n 0\n \n 0\n \n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(588\\)\n \n 0\n \n 0\n
\n \\(589\\)\n \n 0\n \n 0\n
\n \\(590\\)\n \n 0\n \n 0\n
\n \\(591\\)\n \n 0\n \n 0\n
\n \\(592\\)\n \n \u22120.366025\n \n \u2212\n \n 1.36603i\n \u22120.366025\n \n \u2212\n \n 1.36603i
\n \\(593\\)\n \n 0\n \n 0\n \n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(594\\)\n \n 0\n \n 0\n
\n \\(595\\)\n \n 0\n \n 0\n
\n \\(596\\)\n \n \u22122.00000\n \n \u22122.00000\n
\n \\(597\\)\n \n 0\n \n 0\n
\n \\(598\\)\n \n 0\n \n 0\n
\n \\(599\\)\n \n 0\n \n 0\n \n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n \u22120.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(600\\)\n \n 0\n \n 0\n
\n \\(601\\)\n \n \u22121.00000\n \n \u2212\n \n 1.00000i\n \u22121.00000\n \n \u2212\n \n 1.00000i\n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(602\\)\n \n 0\n \n 0\n
\n \\(603\\)\n \n 0\n \n 0\n
\n \\(604\\)\n \n 0\n \n 0\n
\n \\(605\\)\n \n \u22121.36603\n \n +\n \n 0.366025i\n \u22121.36603\n \n +\n \n 0.366025i
\n \\(606\\)\n \n 0\n \n 0\n
\n \\(607\\)\n \n 0\n \n 0\n \n \u22120.965926\n \n \u2212\n \n 0.258819i\n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \\(0.0833333\\pi\\)\n
\n \\(608\\)\n \n 0\n \n 0\n
\n \\(609\\)\n \n 0\n \n 0\n
\n \\(610\\)\n \n \u2212\n \n 2.00000i\n \u2212\n \n 2.00000i
\n \\(611\\)\n \n 0\n \n 0\n
\n \\(612\\)\n \n \u22120.866025\n \n \u2212\n \n 0.500000i\n \u22120.866025\n \n \u2212\n \n 0.500000i
\n \\(613\\)\n \n \u22121.00000\n \n +\n \n 1.73205i\n \u22121.00000\n \n +\n \n 1.73205i\n \u22120.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \u22120.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(614\\)\n \n 0\n \n 0\n
\n \\(615\\)\n \n 0\n \n 0\n
\n \\(616\\)\n \n 0\n \n 0\n
\n \\(617\\)\n \n \u22121.00000\n \n +\n \n 1.00000i\n \u22121.00000\n \n +\n \n 1.00000i\n 1.00000i\n \\(0.5\\pi\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(618\\)\n \n 0\n \n 0\n
\n \\(619\\)\n \n 0\n \n 0\n \n 0.965926\n \n \u2212\n \n 0.258819i\n \\(-0.0833333\\pi\\)\n
\n \u22120.965926\n \n +\n \n 0.258819i\n \\(0.916667\\pi\\)\n
\n \\(620\\)\n \n 0\n \n 0\n
\n \\(621\\)\n \n 0\n \n 0\n
\n \\(622\\)\n \n 0\n \n 0\n
\n \\(623\\)\n \n 0\n \n 0\n
\n \\(624\\)\n \n 0\n \n 0\n
\n \\(625\\)\n \n \u22120.500000\n \n \u2212\n \n 0.866025i\n \u22120.500000\n \n \u2212\n \n 0.866025i
\n \\(626\\)\n \n \u22120.366025\n \n \u2212\n \n 1.36603i\n \u22120.366025\n \n \u2212\n \n 1.36603i
\n \\(627\\)\n \n 0\n \n 0\n
\n \\(628\\)\n \n \u22121.00000\n \n \u2212\n \n 1.73205i\n \u22121.00000\n \n \u2212\n \n 1.73205i
\n \\(629\\)\n \n \u22121.00000\n \n +\n \n 1.00000i\n \u22121.00000\n \n +\n \n 1.00000i
\n \\(630\\)\n \n 0\n \n 0\n
\n \\(631\\)\n \n 0\n \n 0\n \n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(632\\)\n \n 0\n \n 0\n
\n \\(633\\)\n \n 0\n \n 0\n
\n \\(634\\)\n \n 0.366025\n \n +\n \n 1.36603i\n 0.366025\n \n +\n \n 1.36603i
\n \\(635\\)\n \n 0\n \n 0\n
\n \\(636\\)\n \n 0\n \n 0\n
\n \\(637\\)\n \n 0\n \n 0\n
\n \\(638\\)\n \n 0\n \n 0\n
\n \\(639\\)\n \n 0\n \n 0\n
\n \\(640\\)\n \n \u22121.36603\n \n +\n \n 0.366025i\n \u22121.36603\n \n +\n \n 0.366025i
\n \\(641\\)\n \n \u22120.366025\n \n \u2212\n \n 1.36603i\n \u22120.366025\n \n \u2212\n \n 1.36603i\n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n \\(642\\)\n \n 0\n \n 0\n
\n \\(643\\)\n \n 0\n \n 0\n \n 0.707107\n \n \u2212\n \n 0.707107i\n \\(-0.250000\\pi\\)\n
\n \u22120.707107\n \n +\n \n 0.707107i\n \\(0.750000\\pi\\)\n
\n \\(644\\)\n \n 0\n \n 0\n
\n \\(645\\)\n \n 0\n \n 0\n
\n \\(646\\)\n \n 0\n \n 0\n
\n \\(647\\)\n \n 0\n \n 0\n \n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n \u22120.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(648\\)\n \n 0.866025\n \n +\n \n 0.500000i\n 0.866025\n \n +\n \n 0.500000i
\n \\(649\\)\n \n 0\n \n 0\n
\n \\(650\\)\n \n 0\n \n 0\n
\n \\(651\\)\n \n 0\n \n 0\n
\n \\(652\\)\n \n 0\n \n 0\n
\n \\(653\\)\n \n 0.366025\n \n \u2212\n \n 1.36603i\n 0.366025\n \n \u2212\n \n 1.36603i\n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \\(654\\)\n \n 0\n \n 0\n
\n \\(655\\)\n \n 0\n \n 0\n
\n \\(656\\)\n \n \u22120.366025\n \n +\n \n 1.36603i\n \u22120.366025\n \n +\n \n 1.36603i
\n \\(657\\)\n \n 1.00000\n \n +\n \n 1.00000i\n 1.00000\n \n +\n \n 1.00000i
\n \\(658\\)\n \n 0\n \n 0\n
\n \\(659\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(660\\)\n \n 0\n \n 0\n
\n \\(661\\)\n \n 0\n \n 0\n \n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n \u22120.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(662\\)\n \n 0\n \n 0\n
\n \\(663\\)\n \n 0\n \n 0\n
\n \\(664\\)\n \n 0\n \n 0\n
\n \\(665\\)\n \n 0\n \n 0\n
\n \\(666\\)\n \n 1.00000\n \n \u2212\n \n 1.00000i\n 1.00000\n \n \u2212\n \n 1.00000i
\n \\(667\\)\n \n 0\n \n 0\n
\n \\(668\\)\n \n 0\n \n 0\n
\n \\(669\\)\n \n 0\n \n 0\n
\n \\(670\\)\n \n 0\n \n 0\n
\n \\(671\\)\n \n 0\n \n 0\n
\n \\(672\\)\n \n 0\n \n 0\n
\n \\(673\\)\n \n \u22121.00000\n \n \u2212\n \n 1.00000i\n \u22121.00000\n \n \u2212\n \n 1.00000i\n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(674\\)\n \n \u22120.366025\n \n +\n \n 1.36603i\n \u22120.366025\n \n +\n \n 1.36603i
\n \\(675\\)\n \n 0\n \n 0\n
\n \\(676\\)\n \n \u22120.500000\n \n +\n \n 0.866025i\n \u22120.500000\n \n +\n \n 0.866025i
\n \\(677\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i\n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(678\\)\n \n 0\n \n 0\n
\n \\(679\\)\n \n 0\n \n 0\n
\n \\(680\\)\n \n 1.00000\n \n +\n \n 1.00000i\n 1.00000\n \n +\n \n 1.00000i
\n \\(681\\)\n \n 0\n \n 0\n
\n \\(682\\)\n \n 0\n \n 0\n
\n \\(683\\)\n \n 0\n \n 0\n \n \u22120.258819\n \n \u2212\n \n 0.965926i\n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \\(0.416667\\pi\\)\n
\n \\(684\\)\n \n 0\n \n 0\n
\n \\(685\\)\n \n 0\n \n 0\n
\n \\(686\\)\n \n 0\n \n 0\n
\n \\(687\\)\n \n 0\n \n 0\n
\n \\(688\\)\n \n 0\n \n 0\n
\n \\(689\\)\n \n 0\n \n 0\n
\n \\(690\\)\n \n 0\n \n 0\n
\n \\(691\\)\n \n 0\n \n 0\n \n 0.258819\n \n \u2212\n \n 0.965926i\n \\(-0.416667\\pi\\)\n
\n \u22120.258819\n \n +\n \n 0.965926i\n \\(0.583333\\pi\\)\n
\n \\(692\\)\n \n 1.00000\n \n \u2212\n \n 1.00000i\n 1.00000\n \n \u2212\n \n 1.00000i
\n \\(693\\)\n \n 0\n \n 0\n
\n \\(694\\)\n \n 0\n \n 0\n
\n \\(695\\)\n \n 0\n \n 0\n
\n \\(696\\)\n \n 0\n \n 0\n
\n \\(697\\)\n \n 1.36603\n \n \u2212\n \n 0.366025i\n 1.36603\n \n \u2212\n \n 0.366025i
\n \\(698\\)\n \n 0\n \n 0\n
\n \\(699\\)\n \n 0\n \n 0\n
\n \\(700\\)\n \n 0\n \n 0\n
\n \\(701\\)\n \n 0\n \n 0\n \n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(702\\)\n \n 0\n \n 0\n
\n \\(703\\)\n \n 0\n \n 0\n
\n \\(704\\)\n \n 0\n \n 0\n
\n \\(705\\)\n \n 0\n \n 0\n
\n \\(706\\)\n \n \u2212\n \n 2.00000i\n \u2212\n \n 2.00000i
\n \\(707\\)\n \n 0\n \n 0\n
\n \\(708\\)\n \n 0\n \n 0\n
\n \\(709\\)\n \n \u22121.36603\n \n \u2212\n \n 0.366025i\n \u22121.36603\n \n \u2212\n \n 0.366025i\n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(710\\)\n \n 0\n \n 0\n
\n \\(711\\)\n \n 0\n \n 0\n
\n \\(712\\)\n \n 0\n \n 0\n
\n \\(713\\)\n \n 0\n \n 0\n
\n \\(714\\)\n \n 0\n \n 0\n
\n \\(715\\)\n \n 0\n \n 0\n
\n \\(716\\)\n \n 0\n \n 0\n
\n \\(717\\)\n \n 0\n \n 0\n
\n \\(718\\)\n \n 0\n \n 0\n
\n \\(719\\)\n \n 0\n \n 0\n \n \u22120.965926\n \n \u2212\n \n 0.258819i\n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \\(0.0833333\\pi\\)\n
\n \\(720\\)\n \n \u22121.00000\n \n \u2212\n \n 1.00000i\n \u22121.00000\n \n \u2212\n \n 1.00000i
\n \\(721\\)\n \n 0\n \n 0\n
\n \\(722\\)\n \n 1.00000i\n 1.00000i
\n \\(723\\)\n \n 0\n \n 0\n
\n \\(724\\)\n \n 1.36603\n \n \u2212\n \n 0.366025i\n 1.36603\n \n \u2212\n \n 0.366025i
\n \\(725\\)\n \n 1.36603\n \n \u2212\n \n 0.366025i\n 1.36603\n \n \u2212\n \n 0.366025i
\n \\(726\\)\n \n 0\n \n 0\n
\n \\(727\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(728\\)\n \n 0\n \n 0\n
\n \\(729\\)\n \n 1.00000i\n 1.00000i
\n \\(730\\)\n \n \u22121.00000\n \n \u2212\n \n 1.73205i\n \u22121.00000\n \n \u2212\n \n 1.73205i
\n \\(731\\)\n \n 0\n \n 0\n
\n \\(732\\)\n \n 0\n \n 0\n
\n \\(733\\)\n \n 0\n \n 0\n \n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(734\\)\n \n 0\n \n 0\n
\n \\(735\\)\n \n 0\n \n 0\n
\n \\(736\\)\n \n 0\n \n 0\n
\n \\(737\\)\n \n 0\n \n 0\n
\n \\(738\\)\n \n \u22121.36603\n \n +\n \n 0.366025i\n \u22121.36603\n \n +\n \n 0.366025i
\n \\(739\\)\n \n 0\n \n 0\n \n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(740\\)\n \n \u22121.73205\n \n +\n \n 1.00000i\n \u22121.73205\n \n +\n \n 1.00000i
\n \\(741\\)\n \n 0\n \n 0\n
\n \\(742\\)\n \n 0\n \n 0\n
\n \\(743\\)\n \n 0\n \n 0\n \n 0.707107\n \n \u2212\n \n 0.707107i\n \\(-0.250000\\pi\\)\n
\n \u22120.707107\n \n +\n \n 0.707107i\n \\(0.750000\\pi\\)\n
\n \\(744\\)\n \n 0\n \n 0\n
\n \\(745\\)\n \n 0.732051\n \n +\n \n 2.73205i\n 0.732051\n \n +\n \n 2.73205i
\n \\(746\\)\n \n 0\n \n 0\n
\n \\(747\\)\n \n 0\n \n 0\n
\n \\(748\\)\n \n 0\n \n 0\n
\n \\(749\\)\n \n 0\n \n 0\n
\n \\(750\\)\n \n 0\n \n 0\n
\n \\(751\\)\n \n 0\n \n 0\n \n \u22120.965926\n \n \u2212\n \n 0.258819i\n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \\(0.0833333\\pi\\)\n
\n \\(752\\)\n \n 0\n \n 0\n
\n \\(753\\)\n \n 0\n \n 0\n
\n \\(754\\)\n \n 0\n \n 0\n
\n \\(755\\)\n \n 0\n \n 0\n
\n \\(756\\)\n \n 0\n \n 0\n
\n \\(757\\)\n \n 2.00000i\n 2.00000i\n 1.00000i\n \\(0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(758\\)\n \n 0\n \n 0\n
\n \\(759\\)\n \n 0\n \n 0\n
\n \\(760\\)\n \n 0\n \n 0\n
\n \\(761\\)\n \n 0\n \n 0\n \n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(762\\)\n \n 0\n \n 0\n
\n \\(763\\)\n \n 0\n \n 0\n
\n \\(764\\)\n \n 0\n \n 0\n
\n \\(765\\)\n \n \u22120.366025\n \n +\n \n 1.36603i\n \u22120.366025\n \n +\n \n 1.36603i
\n \\(766\\)\n \n 0\n \n 0\n
\n \\(767\\)\n \n 0\n \n 0\n
\n \\(768\\)\n \n 0\n \n 0\n
\n \\(769\\)\n \n 0\n \n 0\n \n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(770\\)\n \n 0\n \n 0\n
\n \\(771\\)\n \n 0\n \n 0\n
\n \\(772\\)\n \n \u22120.366025\n \n +\n \n 1.36603i\n \u22120.366025\n \n +\n \n 1.36603i
\n \\(773\\)\n \n \u22121.73205\n \n \u2212\n \n 1.00000i\n \u22121.73205\n \n \u2212\n \n 1.00000i\n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n \u22120.866025\n \n \u2212\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n \\(774\\)\n \n 0\n \n 0\n
\n \\(775\\)\n \n 0\n \n 0\n
\n \\(776\\)\n \n 1.00000\n \n +\n \n 1.00000i\n 1.00000\n \n +\n \n 1.00000i
\n \\(777\\)\n \n 0\n \n 0\n
\n \\(778\\)\n \n 2.00000\n \n 2.00000\n
\n \\(779\\)\n \n 0\n \n 0\n
\n \\(780\\)\n \n 0\n \n 0\n
\n \\(781\\)\n \n 0\n \n 0\n
\n \\(782\\)\n \n 0\n \n 0\n
\n \\(783\\)\n \n 0\n \n 0\n
\n \\(784\\)\n \n 0\n \n 0\n
\n \\(785\\)\n \n \u22122.00000\n \n +\n \n 2.00000i\n \u22122.00000\n \n +\n \n 2.00000i
\n \\(786\\)\n \n 0\n \n 0\n
\n \\(787\\)\n \n 0\n \n 0\n \n \u22120.258819\n \n \u2212\n \n 0.965926i\n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \\(0.416667\\pi\\)\n
\n \\(788\\)\n \n 1.36603\n \n \u2212\n \n 0.366025i\n 1.36603\n \n \u2212\n \n 0.366025i
\n \\(789\\)\n \n 0\n \n 0\n
\n \\(790\\)\n \n 0\n \n 0\n
\n \\(791\\)\n \n 0\n \n 0\n
\n \\(792\\)\n \n 0\n \n 0\n
\n \\(793\\)\n \n 0\n \n 0\n
\n \\(794\\)\n \n 0.366025\n \n +\n \n 1.36603i\n 0.366025\n \n +\n \n 1.36603i
\n \\(795\\)\n \n 0\n \n 0\n
\n \\(796\\)\n \n 0\n \n 0\n
\n \\(797\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(798\\)\n \n 0\n \n 0\n
\n \\(799\\)\n \n 0\n \n 0\n
\n \\(800\\)\n \n 0.500000\n \n +\n \n 0.866025i\n 0.500000\n \n +\n \n 0.866025i
\n \\(801\\)\n \n 0\n \n 0\n
\n \\(802\\)\n \n 0.366025\n \n +\n \n 1.36603i\n 0.366025\n \n +\n \n 1.36603i
\n \\(803\\)\n \n 0\n \n 0\n
\n \\(804\\)\n \n 0\n \n 0\n
\n \\(805\\)\n \n 0\n \n 0\n
\n \\(806\\)\n \n 0\n \n 0\n
\n \\(807\\)\n \n 0\n \n 0\n
\n \\(808\\)\n \n 0\n \n 0\n
\n \\(809\\)\n \n 1.36603\n \n \u2212\n \n 0.366025i\n 1.36603\n \n \u2212\n \n 0.366025i\n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(810\\)\n \n 0.366025\n \n \u2212\n \n 1.36603i\n 0.366025\n \n \u2212\n \n 1.36603i
\n \\(811\\)\n \n 0\n \n 0\n \n 0.707107\n \n \u2212\n \n 0.707107i\n \\(-0.250000\\pi\\)\n
\n \u22120.707107\n \n +\n \n 0.707107i\n \\(0.750000\\pi\\)\n
\n \\(812\\)\n \n 0\n \n 0\n
\n \\(813\\)\n \n 0\n \n 0\n
\n \\(814\\)\n \n 0\n \n 0\n
\n \\(815\\)\n \n 0\n \n 0\n
\n \\(816\\)\n \n 0\n \n 0\n
\n \\(817\\)\n \n 0\n \n 0\n
\n \\(818\\)\n \n \u2212\n \n 2.00000i\n \u2212\n \n 2.00000i
\n \\(819\\)\n \n 0\n \n 0\n
\n \\(820\\)\n \n 2.00000\n \n 2.00000\n
\n \\(821\\)\n \n \u22121.36603\n \n \u2212\n \n 0.366025i\n \u22121.36603\n \n \u2212\n \n 0.366025i\n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(822\\)\n \n 0\n \n 0\n
\n \\(823\\)\n \n 0\n \n 0\n \n 0.965926\n \n \u2212\n \n 0.258819i\n \\(-0.0833333\\pi\\)\n
\n \u22120.965926\n \n +\n \n 0.258819i\n \\(0.916667\\pi\\)\n
\n \\(824\\)\n \n 0\n \n 0\n
\n \\(825\\)\n \n 0\n \n 0\n
\n \\(826\\)\n \n 0\n \n 0\n
\n \\(827\\)\n \n 0\n \n 0\n \n \u22120.707107\n \n \u2212\n \n 0.707107i\n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \\(0.250000\\pi\\)\n
\n \\(828\\)\n \n 0\n \n 0\n
\n \\(829\\)\n \n 1.00000\n \n \u2212\n \n 1.73205i\n 1.00000\n \n \u2212\n \n 1.73205i\n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n \\(830\\)\n \n 0\n \n 0\n
\n \\(831\\)\n \n 0\n \n 0\n
\n \\(832\\)\n \n 0\n \n 0\n
\n \\(833\\)\n \n 0\n \n 0\n
\n \\(834\\)\n \n 0\n \n 0\n
\n \\(835\\)\n \n 0\n \n 0\n
\n \\(836\\)\n \n 0\n \n 0\n
\n \\(837\\)\n \n 0\n \n 0\n
\n \\(838\\)\n \n 0\n \n 0\n
\n \\(839\\)\n \n 0\n \n 0\n \n \u22120.707107\n \n \u2212\n \n 0.707107i\n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \\(0.250000\\pi\\)\n
\n \\(840\\)\n \n 0\n \n 0\n
\n \\(841\\)\n \n \u2212\n \n 1.00000i\n \u2212\n \n 1.00000i
\n \\(842\\)\n \n 0\n \n 0\n
\n \\(843\\)\n \n 0\n \n 0\n
\n \\(844\\)\n \n 0\n \n 0\n
\n \\(845\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i
\n \\(846\\)\n \n 0\n \n 0\n
\n \\(847\\)\n \n 0\n \n 0\n
\n \\(848\\)\n \n 0\n \n 0\n
\n \\(849\\)\n \n 0\n \n 0\n
\n \\(850\\)\n \n 0.500000\n \n \u2212\n \n 0.866025i\n 0.500000\n \n \u2212\n \n 0.866025i
\n \\(851\\)\n \n 0\n \n 0\n
\n \\(852\\)\n \n 0\n \n 0\n
\n \\(853\\)\n \n 1.00000\n \n \u2212\n \n 1.00000i\n 1.00000\n \n \u2212\n \n 1.00000i\n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000\n \n \\(0\\)\n
\n \\(854\\)\n \n 0\n \n 0\n
\n \\(855\\)\n \n 0\n \n 0\n
\n \\(856\\)\n \n 0\n \n 0\n
\n \\(857\\)\n \n 1.36603\n \n \u2212\n \n 0.366025i\n 1.36603\n \n \u2212\n \n 0.366025i\n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(858\\)\n \n 0\n \n 0\n
\n \\(859\\)\n \n 0\n \n 0\n \n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(860\\)\n \n 0\n \n 0\n
\n \\(861\\)\n \n 0\n \n 0\n
\n \\(862\\)\n \n 0\n \n 0\n
\n \\(863\\)\n \n 0\n \n 0\n \n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(864\\)\n \n 0\n \n 0\n
\n \\(865\\)\n \n \u22121.73205\n \n \u2212\n \n 1.00000i\n \u22121.73205\n \n \u2212\n \n 1.00000i
\n \\(866\\)\n \n \u22121.00000\n \n \u2212\n \n 1.73205i\n \u22121.00000\n \n \u2212\n \n 1.73205i
\n \\(867\\)\n \n 0\n \n 0\n
\n \\(868\\)\n \n 0\n \n 0\n
\n \\(869\\)\n \n 0\n \n 0\n
\n \\(870\\)\n \n 0\n \n 0\n
\n \\(871\\)\n \n 0\n \n 0\n
\n \\(872\\)\n \n 0.366025\n \n +\n \n 1.36603i\n 0.366025\n \n +\n \n 1.36603i
\n \\(873\\)\n \n \u22120.366025\n \n +\n \n 1.36603i\n \u22120.366025\n \n +\n \n 1.36603i
\n \\(874\\)\n \n 0\n \n 0\n
\n \\(875\\)\n \n 0\n \n 0\n
\n \\(876\\)\n \n 0\n \n 0\n
\n \\(877\\)\n \n \u22120.366025\n \n +\n \n 1.36603i\n \u22120.366025\n \n +\n \n 1.36603i\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(878\\)\n \n 0\n \n 0\n
\n \\(879\\)\n \n 0\n \n 0\n
\n \\(880\\)\n \n 0\n \n 0\n
\n \\(881\\)\n \n \u22121.00000\n \n +\n \n 1.00000i\n \u22121.00000\n \n +\n \n 1.00000i\n 1.00000i\n \\(0.5\\pi\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(882\\)\n \n 0\n \n 0\n
\n \\(883\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(884\\)\n \n 0\n \n 0\n
\n \\(885\\)\n \n 0\n \n 0\n
\n \\(886\\)\n \n 0\n \n 0\n
\n \\(887\\)\n \n 0\n \n 0\n \n \u22120.965926\n \n \u2212\n \n 0.258819i\n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \\(0.0833333\\pi\\)\n
\n \\(888\\)\n \n 0\n \n 0\n
\n \\(889\\)\n \n 0\n \n 0\n
\n \\(890\\)\n \n 0\n \n 0\n
\n \\(891\\)\n \n 0\n \n 0\n
\n \\(892\\)\n \n 0\n \n 0\n
\n \\(893\\)\n \n 0\n \n 0\n
\n \\(894\\)\n \n 0\n \n 0\n
\n \\(895\\)\n \n 0\n \n 0\n
\n \\(896\\)\n \n 0\n \n 0\n
\n \\(897\\)\n \n 0\n \n 0\n
\n \\(898\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i
\n \\(899\\)\n \n 0\n \n 0\n
\n \\(900\\)\n \n \u22120.500000\n \n +\n \n 0.866025i\n \u22120.500000\n \n +\n \n 0.866025i
\n \\(901\\)\n \n 0\n \n 0\n
\n \\(902\\)\n \n 0\n \n 0\n
\n \\(903\\)\n \n 0\n \n 0\n
\n \\(904\\)\n \n 1.00000\n \n \u2212\n \n 1.00000i\n 1.00000\n \n \u2212\n \n 1.00000i
\n \\(905\\)\n \n \u22121.00000\n \n \u2212\n \n 1.73205i\n \u22121.00000\n \n \u2212\n \n 1.73205i
\n \\(906\\)\n \n 0\n \n 0\n
\n \\(907\\)\n \n 0\n \n 0\n \n 0.965926\n \n \u2212\n \n 0.258819i\n \\(-0.0833333\\pi\\)\n
\n \u22120.965926\n \n +\n \n 0.258819i\n \\(0.916667\\pi\\)\n
\n \\(908\\)\n \n 0\n \n 0\n
\n \\(909\\)\n \n 0\n \n 0\n
\n \\(910\\)\n \n 0\n \n 0\n
\n \\(911\\)\n \n 0\n \n 0\n \n \u22120.707107\n \n \u2212\n \n 0.707107i\n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \\(0.250000\\pi\\)\n
\n \\(912\\)\n \n 0\n \n 0\n
\n \\(913\\)\n \n 0\n \n 0\n
\n \\(914\\)\n \n 1.00000\n \n \u2212\n \n 1.73205i\n 1.00000\n \n \u2212\n \n 1.73205i
\n \\(915\\)\n \n 0\n \n 0\n
\n \\(916\\)\n \n 2.00000i\n 2.00000i
\n \\(917\\)\n \n 0\n \n 0\n
\n \\(918\\)\n \n 0\n \n 0\n
\n \\(919\\)\n \n 0\n \n 0\n \n \u22120.500000\n \n \u2212\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(920\\)\n \n 0\n \n 0\n
\n \\(921\\)\n \n 0\n \n 0\n
\n \\(922\\)\n \n 0\n \n 0\n
\n \\(923\\)\n \n 0\n \n 0\n
\n \\(924\\)\n \n 0\n \n 0\n
\n \\(925\\)\n \n 1.00000\n \n +\n \n 1.00000i\n 1.00000\n \n +\n \n 1.00000i
\n \\(926\\)\n \n 0\n \n 0\n
\n \\(927\\)\n \n 0\n \n 0\n
\n \\(928\\)\n \n 1.36603\n \n \u2212\n \n 0.366025i\n 1.36603\n \n \u2212\n \n 0.366025i
\n \\(929\\)\n \n \u22120.366025\n \n +\n \n 1.36603i\n \u22120.366025\n \n +\n \n 1.36603i\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(930\\)\n \n 0\n \n 0\n
\n \\(931\\)\n \n 0\n \n 0\n
\n \\(932\\)\n \n 1.00000\n \n \u2212\n \n 1.00000i\n 1.00000\n \n \u2212\n \n 1.00000i
\n \\(933\\)\n \n 0\n \n 0\n
\n \\(934\\)\n \n 0\n \n 0\n
\n \\(935\\)\n \n 0\n \n 0\n
\n \\(936\\)\n \n 0\n \n 0\n
\n \\(937\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n \u22121.00000\n \n \\(\\pi\\)\n
\n \\(938\\)\n \n 0\n \n 0\n
\n \\(939\\)\n \n 0\n \n 0\n
\n \\(940\\)\n \n 0\n \n 0\n
\n \\(941\\)\n \n 1.36603\n \n \u2212\n \n 0.366025i\n 1.36603\n \n \u2212\n \n 0.366025i\n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(942\\)\n \n 0\n \n 0\n
\n \\(943\\)\n \n 0\n \n 0\n
\n \\(944\\)\n \n 0\n \n 0\n
\n \\(945\\)\n \n 0\n \n 0\n
\n \\(946\\)\n \n 0\n \n 0\n
\n \\(947\\)\n \n 0\n \n 0\n \n \u22120.965926\n \n \u2212\n \n 0.258819i\n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \\(0.0833333\\pi\\)\n
\n \\(948\\)\n \n 0\n \n 0\n
\n \\(949\\)\n \n 0\n \n 0\n
\n \\(950\\)\n \n 0\n \n 0\n
\n \\(951\\)\n \n 0\n \n 0\n
\n \\(952\\)\n \n 0\n \n 0\n
\n \\(953\\)\n \n 0\n \n 0\n \n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(954\\)\n \n 0\n \n 0\n
\n \\(955\\)\n \n 0\n \n 0\n
\n \\(956\\)\n \n 0\n \n 0\n
\n \\(957\\)\n \n 0\n \n 0\n
\n \\(958\\)\n \n 0\n \n 0\n
\n \\(959\\)\n \n 0\n \n 0\n
\n \\(960\\)\n \n 0\n \n 0\n
\n \\(961\\)\n \n \u22120.866025\n \n +\n \n 0.500000i\n \u22120.866025\n \n +\n \n 0.500000i
\n \\(962\\)\n \n 0\n \n 0\n
\n \\(963\\)\n \n 0\n \n 0\n
\n \\(964\\)\n \n \u22121.36603\n \n \u2212\n \n 0.366025i\n \u22121.36603\n \n \u2212\n \n 0.366025i
\n \\(965\\)\n \n 2.00000\n \n 2.00000\n
\n \\(966\\)\n \n 0\n \n 0\n
\n \\(967\\)\n \n 0\n \n 0\n \n \u2212\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(968\\)\n \n 0.500000\n \n +\n \n 0.866025i\n 0.500000\n \n +\n \n 0.866025i
\n \\(969\\)\n \n 0\n \n 0\n
\n \\(970\\)\n \n 1.00000\n \n \u2212\n \n 1.73205i\n 1.00000\n \n \u2212\n \n 1.73205i
\n \\(971\\)\n \n 0\n \n 0\n \n 0.866025\n \n \u2212\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \u22120.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(972\\)\n \n 0\n \n 0\n
\n \\(973\\)\n \n 0\n \n 0\n
\n \\(974\\)\n \n 0\n \n 0\n
\n \\(975\\)\n \n 0\n \n 0\n
\n \\(976\\)\n \n \u22121.36603\n \n +\n \n 0.366025i\n \u22121.36603\n \n +\n \n 0.366025i
\n \\(977\\)\n \n 0\n \n 0\n \n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n \u22120.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(978\\)\n \n 0\n \n 0\n
\n \\(979\\)\n \n 0\n \n 0\n
\n \\(980\\)\n \n 0\n \n 0\n
\n \\(981\\)\n \n \u22121.00000\n \n +\n \n 1.00000i\n \u22121.00000\n \n +\n \n 1.00000i
\n \\(982\\)\n \n 0\n \n 0\n
\n \\(983\\)\n \n 0\n \n 0\n \n \u22120.258819\n \n \u2212\n \n 0.965926i\n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \\(0.416667\\pi\\)\n
\n \\(984\\)\n \n 0\n \n 0\n
\n \\(985\\)\n \n \u22121.00000\n \n \u2212\n \n 1.73205i\n \u22121.00000\n \n \u2212\n \n 1.73205i
\n \\(986\\)\n \n \u22121.00000\n \n \u2212\n \n 1.00000i\n \u22121.00000\n \n \u2212\n \n 1.00000i
\n \\(987\\)\n \n 0\n \n 0\n
\n \\(988\\)\n \n 0\n \n 0\n
\n \\(989\\)\n \n 0\n \n 0\n
\n \\(990\\)\n \n 0\n \n 0\n
\n \\(991\\)\n \n 0\n \n 0\n \n \u22120.258819\n \n \u2212\n \n 0.965926i\n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \\(0.416667\\pi\\)\n
\n \\(992\\)\n \n 0\n \n 0\n
\n \\(993\\)\n \n 0\n \n 0\n
\n \\(994\\)\n \n 0\n \n 0\n
\n \\(995\\)\n \n 0\n \n 0\n
\n \\(996\\)\n \n 0\n \n 0\n
\n \\(997\\)\n \n 1.36603\n \n \u2212\n \n 0.366025i\n 1.36603\n \n \u2212\n \n 0.366025i\n 0.500000\n \n \u2212\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(998\\)\n \n 0\n \n 0\n
\n \\(999\\)\n \n 0\n \n 0\n
\n (See \\(a_n\\) instead)\n
\n (See \\(a_n\\) instead)\n
\n (See \\(a_n\\) instead)\n
\n (See only \\(a_p\\))\n
\n (See only \\(a_p\\))\n
\n (See only \\(a_p\\))\n
\u2003\u2003\u2003\u2003\u2003\u2003\u2003By twisting character
CharParityOrdTypeTwistMinDim
1.1even1trivial3332.1.bc.b.2027.14
4.3odd2CM3332.1.bc.b.2027.14
7.2even3inner3332.1.bc.b.667.14
7.3odd668.1.f.a.55.1yes2
7.4even33332.1.m.b.2843.12
7.5odd63332.1.bc.c.667.14
7.6odd23332.1.bc.c.2027.14
17.13even4inner3332.1.bc.b.2223.14
21.17even6612.1.l.a.55.12
28.3even668.1.f.a.55.1yes2
28.11odd63332.1.m.b.2843.12
28.19even63332.1.bc.c.667.14
28.23odd6inner3332.1.bc.b.667.14
28.27even23332.1.bc.c.2027.14
35.3even121700.1.n.a.599.12
35.17even121700.1.n.b.599.12
35.24odd61700.1.p.a.1551.12
56.3even61088.1.p.a.191.12
56.45odd61088.1.p.a.191.12
68.47odd4inner3332.1.bc.b.2223.14
84.59odd6612.1.l.a.55.12
119.3even481156.1.g.b.155.18
119.10even481156.1.g.b.179.18
119.13odd43332.1.bc.c.2223.14
119.24even481156.1.g.b.179.28
119.30even12inner3332.1.bc.b.863.14
119.31even481156.1.g.b.155.28
119.38odd121156.1.f.b.251.12
119.45even481156.1.g.b.399.18
119.47odd123332.1.bc.c.863.14
119.59odd241156.1.c.b.579.12
119.66odd241156.1.d.a.1155.22
119.73even481156.1.g.b.423.28
119.80even481156.1.g.b.423.18
119.81even123332.1.m.b.3039.12
119.87odd241156.1.d.a.1155.12
119.94odd241156.1.c.b.579.22
119.101odd61156.1.f.b.327.12
119.108even481156.1.g.b.399.28
119.115odd1268.1.f.a.47.1&check;2
140.3odd121700.1.n.a.599.12
140.59even61700.1.p.a.1551.12
140.87odd121700.1.n.b.599.12
357.353even12612.1.l.a.523.12
476.3odd481156.1.g.b.155.18
476.31odd481156.1.g.b.155.28
476.47even123332.1.bc.c.863.14
476.59even241156.1.c.b.579.12
476.87even241156.1.d.a.1155.12
476.115even1268.1.f.a.47.1&check;2
476.143odd481156.1.g.b.179.28
476.199odd481156.1.g.b.423.18
476.227odd481156.1.g.b.399.28
476.251even43332.1.bc.c.2223.14
476.283odd481156.1.g.b.399.18
476.311odd481156.1.g.b.423.28
476.319odd123332.1.m.b.3039.12
476.339even61156.1.f.b.327.12
476.367odd481156.1.g.b.179.18
476.387odd12inner3332.1.bc.b.863.14
476.395even121156.1.f.b.251.12
476.423even241156.1.d.a.1155.22
476.451even241156.1.c.b.579.22
595.234odd121700.1.p.a.251.12
595.353even121700.1.n.b.999.12
595.472even121700.1.n.a.999.12
952.115even121088.1.p.a.319.12
952.829odd121088.1.p.a.319.12
1428.1067odd12612.1.l.a.523.12
2380.1067odd121700.1.n.a.999.12
2380.1543odd121700.1.n.b.999.12
2380.2019even121700.1.p.a.251.12
\u2003\u2003\u2003\u2003\u2003\u2003\u2003\u2003By twisted newform
TwistMinDimCharParityOrdType
68.1.f.a.47.1&check;2119.115odd12
68.1.f.a.47.1&check;2476.115even12
68.1.f.a.55.1yes27.3odd6
68.1.f.a.55.1yes228.3even6
612.1.l.a.55.1221.17even6
612.1.l.a.55.1284.59odd6
612.1.l.a.523.12357.353even12
612.1.l.a.523.121428.1067odd12
1088.1.p.a.191.1256.3even6
1088.1.p.a.191.1256.45odd6
1088.1.p.a.319.12952.115even12
1088.1.p.a.319.12952.829odd12
1156.1.c.b.579.12119.59odd24
1156.1.c.b.579.12476.59even24
1156.1.c.b.579.22119.94odd24
1156.1.c.b.579.22476.451even24
1156.1.d.a.1155.12119.87odd24
1156.1.d.a.1155.12476.87even24
1156.1.d.a.1155.22119.66odd24
1156.1.d.a.1155.22476.423even24
1156.1.f.b.251.12119.38odd12
1156.1.f.b.251.12476.395even12
1156.1.f.b.327.12119.101odd6
1156.1.f.b.327.12476.339even6
1156.1.g.b.155.18119.3even48
1156.1.g.b.155.18476.3odd48
1156.1.g.b.155.28119.31even48
1156.1.g.b.155.28476.31odd48
1156.1.g.b.179.18119.10even48
1156.1.g.b.179.18476.367odd48
1156.1.g.b.179.28119.24even48
1156.1.g.b.179.28476.143odd48
1156.1.g.b.399.18119.45even48
1156.1.g.b.399.18476.283odd48
1156.1.g.b.399.28119.108even48
1156.1.g.b.399.28476.227odd48
1156.1.g.b.423.18119.80even48
1156.1.g.b.423.18476.199odd48
1156.1.g.b.423.28119.73even48
1156.1.g.b.423.28476.311odd48
1700.1.n.a.599.1235.3even12
1700.1.n.a.599.12140.3odd12
1700.1.n.a.999.12595.472even12
1700.1.n.a.999.122380.1067odd12
1700.1.n.b.599.1235.17even12
1700.1.n.b.599.12140.87odd12
1700.1.n.b.999.12595.353even12
1700.1.n.b.999.122380.1543odd12
1700.1.p.a.251.12595.234odd12
1700.1.p.a.251.122380.2019even12
1700.1.p.a.1551.1235.24odd6
1700.1.p.a.1551.12140.59even6
3332.1.m.b.2843.127.4even3
3332.1.m.b.2843.1228.11odd6
3332.1.m.b.3039.12119.81even12
3332.1.m.b.3039.12476.319odd12
3332.1.bc.b.667.147.2even3inner
3332.1.bc.b.667.1428.23odd6inner
3332.1.bc.b.863.14119.30even12inner
3332.1.bc.b.863.14476.387odd12inner
3332.1.bc.b.2027.141.1even1trivial
3332.1.bc.b.2027.144.3odd2CM
3332.1.bc.b.2223.1417.13even4inner
3332.1.bc.b.2223.1468.47odd4inner
3332.1.bc.c.667.147.5odd6
3332.1.bc.c.667.1428.19even6
3332.1.bc.c.863.14119.47odd12
3332.1.bc.c.863.14476.47even12
3332.1.bc.c.2027.147.6odd2
3332.1.bc.c.2027.1428.27even2
3332.1.bc.c.2223.14119.13odd4
3332.1.bc.c.2223.14476.251even4
", "statics": {"paragraph": 22, "paragraph.text": 24, "table": 8, "title": 4, "table.complex": 4, "paragraph.equation-inline": 2}, "url": "https://www.lmfdb.org/ModularForm/GL2/Q/holomorphic/3332/1/bc/b/2027/1/", "content": "Show commands: Magma/ PariGP/ SageMath\n\n[N,k,chi] = [3332,1,Mod(667,3332)] mf = mfinit([N,k,chi],0) lf = mfeigenbasis(mf)\n\nfrom sage.modular.dirichlet import DirichletCharacter H = DirichletGroup(3332, base_ring=CyclotomicField(12)) chi = DirichletCharacter(H, H._module([6, 4, 9])) N = Newforms(chi, 1, names=\"a\")\n\n//Please install CHIMP (https://github.com/edgarcosta/CHIMP) if you want to run this code chi := DirichletCharacter(\"3332.667\"); S:= CuspForms(chi, 1); N := Newforms(S);\n\n| Level | \\( N \\) | \\(=\\) | \\( 3332 = 2^{2} \\cdot 7^{2} \\cdot 17 \\) |\n|---|---|---|---|\n| Weight | \\( k \\) | \\(=\\) | \\( 1 \\) |\n| Character orbit | \\([\\chi]\\) | \\(=\\) | 3332.bc
order
degree
minimal |\n\n## Newform invariants\n\nsage:\u00a0f = N[0] \\# Warning: the index may be different\n\ngp:\u00a0f = lf[1] \\\\ Warning: the index may be different\n\n
Self dualno
Analytic conductor\\(1.66288462209\\)
Analytic rank\\(0\\)
Dimension\\(4\\)
Coefficient field\\(\\Q(\\zeta_{12})\\)
gp:\u00a0f.mod \\\\ as an extension of the character field
Defining polynomial\\( x^{4} - x^{2} + 1 \\)
Coefficient ring\\(\\Z[a_1, a_2]\\)
Coefficient ring index\\( 1 \\)
Twist minimalno (minimal twist has level 68)
Projective image\\(D_{4}\\)
Projective fieldGalois closure of<br>4.2.19652.1
Artin image$C_4\\wr C_2\\times C_6$
Artin fieldGalois closure of<br>\\(\\mathbb{Q}[x]/(x^{48} - \\cdots)\\)
\n\n## Embedding invariants\n\n| Embedding label | | | 2027.1 |\n|---|---|---|---|\n| Root | | | \\(0.866025 - 0.500000i\\) of defining polynomial |\n| Character | \\(\\chi\\) | \\(=\\) | 3332.2027 |\n| Dual form | | | 3332.1.bc.b.863.1 |\n\nsage:\u00a0f.q_expansion() \\# note that sage often uses an isomorphic number field\n\ngp:\u00a0mfcoefs(f, 20)\n\n| \\(f(q)\\) | \\(=\\) | \\(q+(-0.866025 + 0.500000i) q^{2} +(0.500000 - 0.866025i) q^{4} +(-1.36603 - 0.366025i) q^{5} +1.00000i q^{8} +(-0.866025 + 0.500000i) q^{9} +(1.36603 - 0.366025i) q^{10} +(-0.500000 - 0.866025i) q^{16} +(-0.500000 + 0.866025i) q^{17} +(0.500000 - 0.866025i) q^{18} +(-1.00000 + 1.00000i) q^{20} +(0.866025 + 0.500000i) q^{25} +(1.00000 - 1.00000i) q^{29} +(0.866025 + 0.500000i) q^{32} -1.00000i q^{34} +1.00000i q^{36} +(1.36603 + 0.366025i) q^{37} +(0.366025 - 1.36603i) q^{40} +(-1.00000 - 1.00000i) q^{41} +(1.36603 - 0.366025i) q^{45} -1.00000 q^{50} +(-0.366025 + 1.36603i) q^{58} +(0.366025 - 1.36603i) q^{61} -1.00000 q^{64} +(0.500000 + 0.866025i) q^{68} +(-0.500000 - 0.866025i) q^{72} +(-0.366025 - 1.36603i) q^{73} +(-1.36603 + 0.366025i) q^{74} +(0.366025 + 1.36603i) q^{80} +(0.500000 - 0.866025i) q^{81} +(1.36603 + 0.366025i) q^{82} +(1.00000 - 1.00000i) q^{85} +(-1.00000 + 1.00000i) q^{90} +(1.00000 - 1.00000i) q^{97} +O(q^{100})\\) |\n|---|---|---|\n| \\(\\operatorname{Tr}(f)(q)\\) | \\(=\\) | \\( 4 q + 2 q^{4} - 2 q^{5} + 2 q^{10} - 2 q^{16} - 2 q^{17} + 2 q^{18} - 4 q^{20} + 4 q^{29} + 2 q^{37} - 2 q^{40} - 4 q^{41} + 2 q^{45} - 4 q^{50} + 2 q^{58} - 2 q^{61} - 4 q^{64} + 2 q^{68} - 2 q^{72} + 2 q^{73}+ \\cdots + 4 q^{97}+O(q^{100}) \\) |\n\n## Character values\n\nWe give the values of $\\chi$ on generators for $\\left(\\mathbb{Z}/3332\\mathbb{Z}\\right)^\\times$ .\n\n| \\(n\\) | \\(785\\) | \\(885\\) | \\(1667\\) |\n|---|---|---|---|\n| \\(\\chi(n)\\) | \\(e\\left(\\frac{3}{4}\\right)\\) | \\(e\\left(\\frac{2}{3}\\right)\\) | \\(-1\\) |\n\n## Coefficient data\n\nFor each \\(n\\) we display the coefficients of the \\(q\\)-expansion \\(a_n\\), the Satake parameters\\(\\alpha_p\\),\nand the Satake angles \\(\\theta_p = \\textrm{Arg}(\\alpha_p)\\).\n\n( See \\(a_n\\) instead)\n\n( See \\(a_n\\) instead)\n\n( See \\(a_n\\) instead)\n\n( See only \\(a_p\\))\n\n( See only \\(a_p\\))\n\n( See only \\(a_p\\))\n\n
\\(n\\)\\(a_n\\)\\(a_n / n^{(k-1)/2}\\)\\( \\alpha_n \\)\\( \\theta_n \\)
\\(p\\)\\(a_p\\)\\(a_p / p^{(k-1)/2}\\)\\( \\alpha_p\\)\\( \\theta_p \\)
\\(2\\)\u22120.866025+0.500000<br>i\u22120.866025+0.500000<br>i
\\(3\\)00\u22120.258819\u22120.965926<br>i\\(-0.583333\\pi\\)
0.258819+0.965926<br>i\\(0.416667\\pi\\)
\\(4\\)0.500000\u22120.866025<br>i0.500000\u22120.866025<br>i
\\(5\\)\u22121.36603\u22120.366025<br>i\u22121.36603\u22120.366025<br>i\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(6\\)00
\\(7\\)00
\\(8\\)1.00000<br>i1.00000<br>i
\\(9\\)\u22120.866025+0.500000<br>i\u22120.866025+0.500000<br>i
\\(10\\)1.36603\u22120.366025<br>i1.36603\u22120.366025<br>i
\\(11\\)000.965926\u22120.258819<br>i\\(-0.0833333\\pi\\)
\u22120.965926+0.258819<br>i\\(0.916667\\pi\\)
\\(12\\)00
\\(13\\)00\u22121.00000<br>i\\(-0.5\\pi\\)
1.00000<br>i\\(0.5\\pi\\)
\\(14\\)00
\\(15\\)00
\\(16\\)\u22120.500000\u22120.866025<br>i\u22120.500000\u22120.866025<br>i
\\(17\\)\u22120.500000+0.866025<br>i\u22120.500000+0.866025<br>i
\\(18\\)0.500000\u22120.866025<br>i0.500000\u22120.866025<br>i
\\(19\\)000.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(20\\)\u22121.00000+1.00000<br>i\u22121.00000+1.00000<br>i
\\(21\\)00
\\(22\\)00
\\(23\\)000.258819\u22120.965926<br>i\\(-0.416667\\pi\\)
\u22120.258819+0.965926<br>i\\(0.583333\\pi\\)
\\(24\\)00
\\(25\\)0.866025+0.500000<br>i0.866025+0.500000<br>i
\\(26\\)00
\\(27\\)00
\\(28\\)00
\\(29\\)1.00000\u22121.00000<br>i1.00000\u22121.00000<br>i\u22121.00000<br>i\\(-0.5\\pi\\)
1.00000\\(0\\)
\\(30\\)00
\\(31\\)00\u22120.258819\u22120.965926<br>i\\(-0.583333\\pi\\)
0.258819+0.965926<br>i\\(0.416667\\pi\\)
\\(32\\)0.866025+0.500000<br>i0.866025+0.500000<br>i
\\(33\\)00
\\(34\\)\u22121.00000<br>i\u22121.00000<br>i
\\(35\\)00
\\(36\\)1.00000<br>i1.00000<br>i
\\(37\\)1.36603+0.366025<br>i1.36603+0.366025<br>i0.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
0.500000+0.866025<br>i\\(0.333333\\pi\\)
\\(38\\)00
\\(39\\)00
\\(40\\)0.366025\u22121.36603<br>i0.366025\u22121.36603<br>i
\\(41\\)\u22121.00000\u22121.00000<br>i\u22121.00000\u22121.00000<br>i\u22121.00000<br>i\\(-0.5\\pi\\)
\u22121.00000\\(\\pi\\)
\\(42\\)00
\\(43\\)00\u22121.00000<br>i\\(-0.5\\pi\\)
1.00000<br>i\\(0.5\\pi\\)
\\(44\\)00
\\(45\\)1.36603\u22120.366025<br>i1.36603\u22120.366025<br>i
\\(46\\)00
\\(47\\)00\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
0.500000+0.866025<br>i\\(0.333333\\pi\\)
\\(48\\)00
\\(49\\)00
\\(50\\)\u22121.00000\u22121.00000
\\(51\\)00
\\(52\\)00
\\(53\\)000.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
\u22120.500000+0.866025<br>i\\(0.666667\\pi\\)
\\(54\\)00
\\(55\\)00
\\(56\\)00
\\(57\\)00
\\(58\\)\u22120.366025+1.36603<br>i\u22120.366025+1.36603<br>i
\\(59\\)00\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
0.866025+0.500000<br>i\\(0.166667\\pi\\)
\\(60\\)00
\\(61\\)0.366025\u22121.36603<br>i0.366025\u22121.36603<br>i\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
0.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
\\(62\\)00
\\(63\\)00
\\(64\\)\u22121.00000\u22121.00000
\\(65\\)00
\\(66\\)00
\\(67\\)000.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
\u22120.500000+0.866025<br>i\\(0.666667\\pi\\)
\\(68\\)0.500000+0.866025<br>i0.500000+0.866025<br>i
\\(69\\)00
\\(70\\)00
\\(71\\)000.707107\u22120.707107<br>i\\(-0.250000\\pi\\)
\u22120.707107+0.707107<br>i\\(0.750000\\pi\\)
\\(72\\)\u22120.500000\u22120.866025<br>i\u22120.500000\u22120.866025<br>i
\\(73\\)\u22120.366025\u22121.36603<br>i\u22120.366025\u22121.36603<br>i\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
0.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
\\(74\\)\u22121.36603+0.366025<br>i\u22121.36603+0.366025<br>i
\\(75\\)00
\\(76\\)00
\\(77\\)00
\\(78\\)00
\\(79\\)000.258819\u22120.965926<br>i\\(-0.416667\\pi\\)
\u22120.258819+0.965926<br>i\\(0.583333\\pi\\)
\\(80\\)0.366025+1.36603<br>i0.366025+1.36603<br>i
\\(81\\)0.500000\u22120.866025<br>i0.500000\u22120.866025<br>i
\\(82\\)1.36603+0.366025<br>i1.36603+0.366025<br>i
\\(83\\)00\u22121.00000<br>i\\(-0.5\\pi\\)
1.00000<br>i\\(0.5\\pi\\)
\\(84\\)00
\\(85\\)1.00000\u22121.00000<br>i1.00000\u22121.00000<br>i
\\(86\\)00
\\(87\\)00
\\(88\\)00
\\(89\\)000.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(90\\)\u22121.00000+1.00000<br>i\u22121.00000+1.00000<br>i
\\(91\\)00
\\(92\\)00
\\(93\\)00
\\(94\\)00
\\(95\\)00
\\(96\\)00
\\(97\\)1.00000\u22121.00000<br>i1.00000\u22121.00000<br>i\u22121.00000<br>i\\(-0.5\\pi\\)
1.00000\\(0\\)
\\(98\\)00
\\(99\\)00
\\(100\\)0.866025\u22120.500000<br>i0.866025\u22120.500000<br>i
\\(101\\)00\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
0.866025+0.500000<br>i\\(0.166667\\pi\\)
\\(102\\)00
\\(103\\)00\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
0.500000+0.866025<br>i\\(0.333333\\pi\\)
\\(104\\)00
\\(105\\)00
\\(106\\)00
\\(107\\)00\u22120.965926\u22120.258819<br>i\\(-0.916667\\pi\\)
0.965926+0.258819<br>i\\(0.0833333\\pi\\)
\\(108\\)00
\\(109\\)1.36603\u22120.366025<br>i1.36603\u22120.366025<br>i0.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
0.866025+0.500000<br>i\\(0.166667\\pi\\)
\\(110\\)00
\\(111\\)00
\\(112\\)00
\\(113\\)\u22121.00000\u22121.00000<br>i\u22121.00000\u22121.00000<br>i\u22121.00000<br>i\\(-0.5\\pi\\)
\u22121.00000\\(\\pi\\)
\\(114\\)00
\\(115\\)00
\\(116\\)\u22120.366025\u22121.36603<br>i\u22120.366025\u22121.36603<br>i
\\(117\\)00
\\(118\\)00
\\(119\\)00
\\(120\\)00
\\(121\\)0.866025\u22120.500000<br>i0.866025\u22120.500000<br>i
\\(122\\)0.366025+1.36603<br>i0.366025+1.36603<br>i
\\(123\\)00
\\(124\\)00
\\(125\\)00
\\(126\\)00
\\(127\\)00\u22121.00000<br>i\\(-0.5\\pi\\)
1.00000<br>i\\(0.5\\pi\\)
\\(128\\)0.866025\u22120.500000<br>i0.866025\u22120.500000<br>i
\\(129\\)00
\\(130\\)00
\\(131\\)00\u22120.965926\u22120.258819<br>i\\(-0.916667\\pi\\)
0.965926+0.258819<br>i\\(0.0833333\\pi\\)
\\(132\\)00
\\(133\\)00
\\(134\\)00
\\(135\\)00
\\(136\\)\u22120.866025\u22120.500000<br>i\u22120.866025\u22120.500000<br>i
\\(137\\)00\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
0.866025+0.500000<br>i\\(0.166667\\pi\\)
\\(138\\)00
\\(139\\)000.707107\u22120.707107<br>i\\(-0.250000\\pi\\)
\u22120.707107+0.707107<br>i\\(0.750000\\pi\\)
\\(140\\)00
\\(141\\)00
\\(142\\)00
\\(143\\)00
\\(144\\)0.866025+0.500000<br>i0.866025+0.500000<br>i
\\(145\\)\u22121.73205+1.00000<br>i\u22121.73205+1.00000<br>i
\\(146\\)1.00000+1.00000<br>i1.00000+1.00000<br>i
\\(147\\)00
\\(148\\)1.00000\u22121.00000<br>i1.00000\u22121.00000<br>i
\\(149\\)\u22121.00000\u22121.73205<br>i\u22121.00000\u22121.73205<br>i\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
\\(150\\)00
\\(151\\)00\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
0.866025+0.500000<br>i\\(0.166667\\pi\\)
\\(152\\)00
\\(153\\)\u22121.00000<br>i\u22121.00000<br>i
\\(154\\)00
\\(155\\)00
\\(156\\)00
\\(157\\)1.00000\u22121.73205<br>i1.00000\u22121.73205<br>i0.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
0.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
\\(158\\)00
\\(159\\)00
\\(160\\)\u22121.00000\u22121.00000<br>i\u22121.00000\u22121.00000<br>i
\\(161\\)00
\\(162\\)1.00000<br>i1.00000<br>i
\\(163\\)000.258819\u22120.965926<br>i\\(-0.416667\\pi\\)
\u22120.258819+0.965926<br>i\\(0.583333\\pi\\)
\\(164\\)\u22121.36603+0.366025<br>i\u22121.36603+0.366025<br>i
\\(165\\)00
\\(166\\)00
\\(167\\)000.707107\u22120.707107<br>i\\(-0.250000\\pi\\)
\u22120.707107+0.707107<br>i\\(0.750000\\pi\\)
\\(168\\)00
\\(169\\)\u22121.00000\u22121.00000
\\(170\\)\u22120.366025+1.36603<br>i\u22120.366025+1.36603<br>i
\\(171\\)00
\\(172\\)00
\\(173\\)1.36603+0.366025<br>i1.36603+0.366025<br>i0.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
0.500000+0.866025<br>i\\(0.333333\\pi\\)
\\(174\\)00
\\(175\\)00
\\(176\\)00
\\(177\\)00
\\(178\\)00
\\(179\\)00\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
0.866025+0.500000<br>i\\(0.166667\\pi\\)
\\(180\\)0.366025\u22121.36603<br>i0.366025\u22121.36603<br>i
\\(181\\)1.00000+1.00000<br>i1.00000+1.00000<br>i1.00000\\(0\\)
1.00000<br>i\\(0.5\\pi\\)
\\(182\\)00
\\(183\\)00
\\(184\\)00
\\(185\\)\u22121.73205\u22121.00000<br>i\u22121.73205\u22121.00000<br>i
\\(186\\)00
\\(187\\)00
\\(188\\)00
\\(189\\)00
\\(190\\)00
\\(191\\)00\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
0.500000+0.866025<br>i\\(0.333333\\pi\\)
\\(192\\)00
\\(193\\)\u22121.36603+0.366025<br>i\u22121.36603+0.366025<br>i\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
\u22120.500000+0.866025<br>i\\(0.666667\\pi\\)
\\(194\\)\u22120.366025+1.36603<br>i\u22120.366025+1.36603<br>i
\\(195\\)00
\\(196\\)00
\\(197\\)1.00000+1.00000<br>i1.00000+1.00000<br>i1.00000\\(0\\)
1.00000<br>i\\(0.5\\pi\\)
\\(198\\)00
\\(199\\)00\u22120.258819\u22120.965926<br>i\\(-0.583333\\pi\\)
0.258819+0.965926<br>i\\(0.416667\\pi\\)
\\(200\\)\u22120.500000+0.866025<br>i\u22120.500000+0.866025<br>i
\\(201\\)00
\\(202\\)00
\\(203\\)00
\\(204\\)00
\\(205\\)1.00000+1.73205<br>i1.00000+1.73205<br>i
\\(206\\)00
\\(207\\)00
\\(208\\)00
\\(209\\)00
\\(210\\)00
\\(211\\)00\u22120.707107\u22120.707107<br>i\\(-0.750000\\pi\\)
0.707107+0.707107<br>i\\(0.250000\\pi\\)
\\(212\\)00
\\(213\\)00
\\(214\\)00
\\(215\\)00
\\(216\\)00
\\(217\\)00
\\(218\\)\u22121.00000+1.00000<br>i\u22121.00000+1.00000<br>i
\\(219\\)00
\\(220\\)00
\\(221\\)00
\\(222\\)00
\\(223\\)00\u22121.00000<br>i\\(-0.5\\pi\\)
1.00000<br>i\\(0.5\\pi\\)
\\(224\\)00
\\(225\\)\u22121.00000\u22121.00000
\\(226\\)1.36603+0.366025<br>i1.36603+0.366025<br>i
\\(227\\)000.965926\u22120.258819<br>i\\(-0.0833333\\pi\\)
\u22120.965926+0.258819<br>i\\(0.916667\\pi\\)
\\(228\\)00
\\(229\\)\u22121.73205+1.00000<br>i\u22121.73205+1.00000<br>i\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(230\\)00
\\(231\\)00
\\(232\\)1.00000+1.00000<br>i1.00000+1.00000<br>i
\\(233\\)1.36603+0.366025<br>i1.36603+0.366025<br>i0.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
0.500000+0.866025<br>i\\(0.333333\\pi\\)
\\(234\\)00
\\(235\\)00
\\(236\\)00
\\(237\\)00
\\(238\\)00
\\(239\\)001.00000\\(0\\)
\u22121.00000\\(\\pi\\)
\\(240\\)00
\\(241\\)\u22120.366025\u22121.36603<br>i\u22120.366025\u22121.36603<br>i\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
0.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
\\(242\\)\u22120.500000+0.866025<br>i\u22120.500000+0.866025<br>i
\\(243\\)00
\\(244\\)\u22121.00000\u22121.00000<br>i\u22121.00000\u22121.00000<br>i
\\(245\\)00
\\(246\\)00
\\(247\\)00
\\(248\\)00
\\(249\\)00
\\(250\\)00
\\(251\\)001.00000\\(0\\)
\u22121.00000\\(\\pi\\)
\\(252\\)00
\\(253\\)00
\\(254\\)00
\\(255\\)00
\\(256\\)\u22120.500000+0.866025<br>i\u22120.500000+0.866025<br>i
\\(257\\)1.73205\u22121.00000<br>i1.73205\u22121.00000<br>i0.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
0.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
\\(258\\)00
\\(259\\)00
\\(260\\)00
\\(261\\)\u22120.366025+1.36603<br>i\u22120.366025+1.36603<br>i
\\(262\\)00
\\(263\\)00\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
0.866025+0.500000<br>i\\(0.166667\\pi\\)
\\(264\\)00
\\(265\\)00
\\(266\\)00
\\(267\\)00
\\(268\\)00
\\(269\\)0.366025+1.36603<br>i0.366025+1.36603<br>i0.866025+0.500000<br>i\\(0.166667\\pi\\)
\u22120.500000+0.866025<br>i\\(0.666667\\pi\\)
\\(270\\)00
\\(271\\)00\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
0.500000+0.866025<br>i\\(0.333333\\pi\\)
\\(272\\)1.000001.00000
\\(273\\)00
\\(274\\)00
\\(275\\)00
\\(276\\)00
\\(277\\)0.366025+1.36603<br>i0.366025+1.36603<br>i0.866025+0.500000<br>i\\(0.166667\\pi\\)
\u22120.500000+0.866025<br>i\\(0.666667\\pi\\)
\\(278\\)00
\\(279\\)00
\\(280\\)00
\\(281\\)001.00000\\(0\\)
\u22121.00000\\(\\pi\\)
\\(282\\)00
\\(283\\)000.965926\u22120.258819<br>i\\(-0.0833333\\pi\\)
\u22120.965926+0.258819<br>i\\(0.916667\\pi\\)
\\(284\\)00
\\(285\\)00
\\(286\\)00
\\(287\\)00
\\(288\\)\u22121.00000\u22121.00000
\\(289\\)\u22120.500000\u22120.866025<br>i\u22120.500000\u22120.866025<br>i
\\(290\\)1.00000\u22121.73205<br>i1.00000\u22121.73205<br>i
\\(291\\)00
\\(292\\)\u22121.36603\u22120.366025<br>i\u22121.36603\u22120.366025<br>i
\\(293\\)2.000002.000001.00000\\(0\\)
1.00000\\(0\\)
\\(294\\)00
\\(295\\)00
\\(296\\)\u22120.366025+1.36603<br>i\u22120.366025+1.36603<br>i
\\(297\\)00
\\(298\\)1.73205+1.00000<br>i1.73205+1.00000<br>i
\\(299\\)00
\\(300\\)00
\\(301\\)00
\\(302\\)00
\\(303\\)00
\\(304\\)00
\\(305\\)\u22121.00000+1.73205<br>i\u22121.00000+1.73205<br>i
\\(306\\)0.500000+0.866025<br>i0.500000+0.866025<br>i
\\(307\\)001.00000\\(0\\)
\u22121.00000\\(\\pi\\)
\\(308\\)00
\\(309\\)00
\\(310\\)00
\\(311\\)00\u22120.258819\u22120.965926<br>i\\(-0.583333\\pi\\)
0.258819+0.965926<br>i\\(0.416667\\pi\\)
\\(312\\)00
\\(313\\)\u22120.366025+1.36603<br>i\u22120.366025+1.36603<br>i0.500000+0.866025<br>i\\(0.333333\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(314\\)2.00000<br>i2.00000<br>i
\\(315\\)00
\\(316\\)00
\\(317\\)0.366025\u22121.36603<br>i0.366025\u22121.36603<br>i\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
0.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
\\(318\\)00
\\(319\\)00
\\(320\\)1.36603+0.366025<br>i1.36603+0.366025<br>i
\\(321\\)00
\\(322\\)00
\\(323\\)00
\\(324\\)\u22120.500000\u22120.866025<br>i\u22120.500000\u22120.866025<br>i
\\(325\\)00
\\(326\\)00
\\(327\\)00
\\(328\\)1.00000\u22121.00000<br>i1.00000\u22121.00000<br>i
\\(329\\)00
\\(330\\)00
\\(331\\)000.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(332\\)00
\\(333\\)\u22121.36603+0.366025<br>i\u22121.36603+0.366025<br>i
\\(334\\)00
\\(335\\)00
\\(336\\)00
\\(337\\)1.00000\u22121.00000<br>i1.00000\u22121.00000<br>i\u22121.00000<br>i\\(-0.5\\pi\\)
1.00000\\(0\\)
\\(338\\)0.866025\u22120.500000<br>i0.866025\u22120.500000<br>i
\\(339\\)00
\\(340\\)\u22120.366025\u22121.36603<br>i\u22120.366025\u22121.36603<br>i
\\(341\\)00
\\(342\\)00
\\(343\\)00
\\(344\\)00
\\(345\\)00
\\(346\\)\u22121.36603+0.366025<br>i\u22121.36603+0.366025<br>i
\\(347\\)000.965926\u22120.258819<br>i\\(-0.0833333\\pi\\)
\u22120.965926+0.258819<br>i\\(0.916667\\pi\\)
\\(348\\)00
\\(349\\)001.00000\\(0\\)
\u22121.00000\\(\\pi\\)
\\(350\\)00
\\(351\\)00
\\(352\\)00
\\(353\\)\u22121.00000+1.73205<br>i\u22121.00000+1.73205<br>i\u22120.500000+0.866025<br>i\\(0.666667\\pi\\)
\u22120.500000+0.866025<br>i\\(0.666667\\pi\\)
\\(354\\)00
\\(355\\)00
\\(356\\)00
\\(357\\)00
\\(358\\)00
\\(359\\)000.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(360\\)0.366025+1.36603<br>i0.366025+1.36603<br>i
\\(361\\)0.500000\u22120.866025<br>i0.500000\u22120.866025<br>i
\\(362\\)\u22121.36603\u22120.366025<br>i\u22121.36603\u22120.366025<br>i
\\(363\\)00
\\(364\\)00
\\(365\\)2.00000<br>i2.00000<br>i
\\(366\\)00
\\(367\\)000.965926\u22120.258819<br>i\\(-0.0833333\\pi\\)
\u22120.965926+0.258819<br>i\\(0.916667\\pi\\)
\\(368\\)00
\\(369\\)1.36603+0.366025<br>i1.36603+0.366025<br>i
\\(370\\)2.000002.00000
\\(371\\)00
\\(372\\)00
\\(373\\)000.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(374\\)00
\\(375\\)00
\\(376\\)00
\\(377\\)00
\\(378\\)00
\\(379\\)000.707107\u22120.707107<br>i\\(-0.250000\\pi\\)
\u22120.707107+0.707107<br>i\\(0.750000\\pi\\)
\\(380\\)00
\\(381\\)00
\\(382\\)00
\\(383\\)000.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(384\\)00
\\(385\\)00
\\(386\\)1.00000\u22121.00000<br>i1.00000\u22121.00000<br>i
\\(387\\)00
\\(388\\)\u22120.366025\u22121.36603<br>i\u22120.366025\u22121.36603<br>i
\\(389\\)\u22121.73205\u22121.00000<br>i\u22121.73205\u22121.00000<br>i\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
\\(390\\)00
\\(391\\)00
\\(392\\)00
\\(393\\)00
\\(394\\)\u22121.36603\u22120.366025<br>i\u22121.36603\u22120.366025<br>i
\\(395\\)00
\\(396\\)00
\\(397\\)0.366025\u22121.36603<br>i0.366025\u22121.36603<br>i\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
0.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
\\(398\\)00
\\(399\\)00
\\(400\\)\u22121.00000<br>i\u22121.00000<br>i
\\(401\\)0.366025\u22121.36603<br>i0.366025\u22121.36603<br>i\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
0.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
\\(402\\)00
\\(403\\)00
\\(404\\)00
\\(405\\)\u22121.00000+1.00000<br>i\u22121.00000+1.00000<br>i
\\(406\\)00
\\(407\\)00
\\(408\\)00
\\(409\\)\u22121.00000+1.73205<br>i\u22121.00000+1.73205<br>i\u22120.500000+0.866025<br>i\\(0.666667\\pi\\)
\u22120.500000+0.866025<br>i\\(0.666667\\pi\\)
\\(410\\)\u22121.73205\u22121.00000<br>i\u22121.73205\u22121.00000<br>i
\\(411\\)00
\\(412\\)00
\\(413\\)00
\\(414\\)00
\\(415\\)00
\\(416\\)00
\\(417\\)00
\\(418\\)00
\\(419\\)00\u22120.707107\u22120.707107<br>i\\(-0.750000\\pi\\)
0.707107+0.707107<br>i\\(0.250000\\pi\\)
\\(420\\)00
\\(421\\)00\u22121.00000<br>i\\(-0.5\\pi\\)
1.00000<br>i\\(0.5\\pi\\)
\\(422\\)00
\\(423\\)00
\\(424\\)00
\\(425\\)\u22120.866025+0.500000<br>i\u22120.866025+0.500000<br>i
\\(426\\)00
\\(427\\)00
\\(428\\)00
\\(429\\)00
\\(430\\)00
\\(431\\)000.965926\u22120.258819<br>i\\(-0.0833333\\pi\\)
\u22120.965926+0.258819<br>i\\(0.916667\\pi\\)
\\(432\\)00
\\(433\\)2.00000<br>i2.00000<br>i1.00000<br>i\\(0.5\\pi\\)
1.00000<br>i\\(0.5\\pi\\)
\\(434\\)00
\\(435\\)00
\\(436\\)0.366025\u22121.36603<br>i0.366025\u22121.36603<br>i
\\(437\\)00
\\(438\\)00
\\(439\\)00\u22120.965926\u22120.258819<br>i\\(-0.916667\\pi\\)
0.965926+0.258819<br>i\\(0.0833333\\pi\\)
\\(440\\)00
\\(441\\)00
\\(442\\)00
\\(443\\)00\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
0.500000+0.866025<br>i\\(0.333333\\pi\\)
\\(444\\)00
\\(445\\)00
\\(446\\)00
\\(447\\)00
\\(448\\)00
\\(449\\)\u22121.00000\u22121.00000<br>i\u22121.00000\u22121.00000<br>i\u22121.00000<br>i\\(-0.5\\pi\\)
\u22121.00000\\(\\pi\\)
\\(450\\)0.866025\u22120.500000<br>i0.866025\u22120.500000<br>i
\\(451\\)00
\\(452\\)\u22121.36603+0.366025<br>i\u22121.36603+0.366025<br>i
\\(453\\)00
\\(454\\)00
\\(455\\)00
\\(456\\)00
\\(457\\)\u22121.73205+1.00000<br>i\u22121.73205+1.00000<br>i\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(458\\)1.00000\u22121.73205<br>i1.00000\u22121.73205<br>i
\\(459\\)00
\\(460\\)00
\\(461\\)001.00000\\(0\\)
\u22121.00000\\(\\pi\\)
\\(462\\)00
\\(463\\)001.00000\\(0\\)
\u22121.00000\\(\\pi\\)
\\(464\\)\u22121.36603\u22120.366025<br>i\u22121.36603\u22120.366025<br>i
\\(465\\)00
\\(466\\)\u22121.36603+0.366025<br>i\u22121.36603+0.366025<br>i
\\(467\\)000.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(468\\)00
\\(469\\)00
\\(470\\)00
\\(471\\)00
\\(472\\)00
\\(473\\)00
\\(474\\)00
\\(475\\)00
\\(476\\)00
\\(477\\)00
\\(478\\)00
\\(479\\)00\u22120.258819\u22120.965926<br>i\\(-0.583333\\pi\\)
0.258819+0.965926<br>i\\(0.416667\\pi\\)
\\(480\\)00
\\(481\\)00
\\(482\\)1.00000+1.00000<br>i1.00000+1.00000<br>i
\\(483\\)00
\\(484\\)\u22121.00000<br>i\u22121.00000<br>i
\\(485\\)\u22121.73205+1.00000<br>i\u22121.73205+1.00000<br>i
\\(486\\)00
\\(487\\)000.965926\u22120.258819<br>i\\(-0.0833333\\pi\\)
\u22120.965926+0.258819<br>i\\(0.916667\\pi\\)
\\(488\\)1.36603+0.366025<br>i1.36603+0.366025<br>i
\\(489\\)00
\\(490\\)00
\\(491\\)00\u22121.00000<br>i\\(-0.5\\pi\\)
1.00000<br>i\\(0.5\\pi\\)
\\(492\\)00
\\(493\\)0.366025+1.36603<br>i0.366025+1.36603<br>i
\\(494\\)00
\\(495\\)00
\\(496\\)00
\\(497\\)00
\\(498\\)00
\\(499\\)000.258819\u22120.965926<br>i\\(-0.416667\\pi\\)
\u22120.258819+0.965926<br>i\\(0.583333\\pi\\)
\\(500\\)00
\\(501\\)00
\\(502\\)00
\\(503\\)00\u22120.707107\u22120.707107<br>i\\(-0.750000\\pi\\)
0.707107+0.707107<br>i\\(0.250000\\pi\\)
\\(504\\)00
\\(505\\)00
\\(506\\)00
\\(507\\)00
\\(508\\)00
\\(509\\)\u22121.00000\u22121.73205<br>i\u22121.00000\u22121.73205<br>i\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
\\(510\\)00
\\(511\\)00
\\(512\\)\u22121.00000<br>i\u22121.00000<br>i
\\(513\\)00
\\(514\\)\u22121.00000+1.73205<br>i\u22121.00000+1.73205<br>i
\\(515\\)00
\\(516\\)00
\\(517\\)00
\\(518\\)00
\\(519\\)00
\\(520\\)00
\\(521\\)1.36603\u22120.366025<br>i1.36603\u22120.366025<br>i0.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
0.866025+0.500000<br>i\\(0.166667\\pi\\)
\\(522\\)\u22120.366025\u22121.36603<br>i\u22120.366025\u22121.36603<br>i
\\(523\\)00\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
0.500000+0.866025<br>i\\(0.333333\\pi\\)
\\(524\\)00
\\(525\\)00
\\(526\\)00
\\(527\\)00
\\(528\\)00
\\(529\\)\u22120.866025\u22120.500000<br>i\u22120.866025\u22120.500000<br>i
\\(530\\)00
\\(531\\)00
\\(532\\)00
\\(533\\)00
\\(534\\)00
\\(535\\)00
\\(536\\)00
\\(537\\)00
\\(538\\)\u22121.00000\u22121.00000<br>i\u22121.00000\u22121.00000<br>i
\\(539\\)00
\\(540\\)00
\\(541\\)1.36603+0.366025<br>i1.36603+0.366025<br>i0.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
0.500000+0.866025<br>i\\(0.333333\\pi\\)
\\(542\\)00
\\(543\\)00
\\(544\\)\u22120.866025+0.500000<br>i\u22120.866025+0.500000<br>i
\\(545\\)\u22122.00000\u22122.00000
\\(546\\)00
\\(547\\)000.707107\u22120.707107<br>i\\(-0.250000\\pi\\)
\u22120.707107+0.707107<br>i\\(0.750000\\pi\\)
\\(548\\)00
\\(549\\)0.366025+1.36603<br>i0.366025+1.36603<br>i
\\(550\\)00
\\(551\\)00
\\(552\\)00
\\(553\\)00
\\(554\\)\u22121.00000\u22121.00000<br>i\u22121.00000\u22121.00000<br>i
\\(555\\)00
\\(556\\)00
\\(557\\)00\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
0.866025+0.500000<br>i\\(0.166667\\pi\\)
\\(558\\)00
\\(559\\)00
\\(560\\)00
\\(561\\)00
\\(562\\)00
\\(563\\)00\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
0.866025+0.500000<br>i\\(0.166667\\pi\\)
\\(564\\)00
\\(565\\)1.00000+1.73205<br>i1.00000+1.73205<br>i
\\(566\\)00
\\(567\\)00
\\(568\\)00
\\(569\\)00\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
0.500000+0.866025<br>i\\(0.333333\\pi\\)
\\(570\\)00
\\(571\\)000.965926\u22120.258819<br>i\\(-0.0833333\\pi\\)
\u22120.965926+0.258819<br>i\\(0.916667\\pi\\)
\\(572\\)00
\\(573\\)00
\\(574\\)00
\\(575\\)00
\\(576\\)0.866025\u22120.500000<br>i0.866025\u22120.500000<br>i
\\(577\\)00\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
0.866025+0.500000<br>i\\(0.166667\\pi\\)
\\(578\\)0.866025+0.500000<br>i0.866025+0.500000<br>i
\\(579\\)00
\\(580\\)2.00000<br>i2.00000<br>i
\\(581\\)00
\\(582\\)00
\\(583\\)00
\\(584\\)1.36603\u22120.366025<br>i1.36603\u22120.366025<br>i
\\(585\\)00
\\(586\\)\u22121.73205+1.00000<br>i\u22121.73205+1.00000<br>i
\\(587\\)00\u22121.00000<br>i\\(-0.5\\pi\\)
1.00000<br>i\\(0.5\\pi\\)
\\(588\\)00
\\(589\\)00
\\(590\\)00
\\(591\\)00
\\(592\\)\u22120.366025\u22121.36603<br>i\u22120.366025\u22121.36603<br>i
\\(593\\)00\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
0.500000+0.866025<br>i\\(0.333333\\pi\\)
\\(594\\)00
\\(595\\)00
\\(596\\)\u22122.00000\u22122.00000
\\(597\\)00
\\(598\\)00
\\(599\\)000.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
\u22120.500000+0.866025<br>i\\(0.666667\\pi\\)
\\(600\\)00
\\(601\\)\u22121.00000\u22121.00000<br>i\u22121.00000\u22121.00000<br>i\u22121.00000<br>i\\(-0.5\\pi\\)
\u22121.00000\\(\\pi\\)
\\(602\\)00
\\(603\\)00
\\(604\\)00
\\(605\\)\u22121.36603+0.366025<br>i\u22121.36603+0.366025<br>i
\\(606\\)00
\\(607\\)00\u22120.965926\u22120.258819<br>i\\(-0.916667\\pi\\)
0.965926+0.258819<br>i\\(0.0833333\\pi\\)
\\(608\\)00
\\(609\\)00
\\(610\\)\u22122.00000<br>i\u22122.00000<br>i
\\(611\\)00
\\(612\\)\u22120.866025\u22120.500000<br>i\u22120.866025\u22120.500000<br>i
\\(613\\)\u22121.00000+1.73205<br>i\u22121.00000+1.73205<br>i\u22120.500000+0.866025<br>i\\(0.666667\\pi\\)
\u22120.500000+0.866025<br>i\\(0.666667\\pi\\)
\\(614\\)00
\\(615\\)00
\\(616\\)00
\\(617\\)\u22121.00000+1.00000<br>i\u22121.00000+1.00000<br>i1.00000<br>i\\(0.5\\pi\\)
\u22121.00000\\(\\pi\\)
\\(618\\)00
\\(619\\)000.965926\u22120.258819<br>i\\(-0.0833333\\pi\\)
\u22120.965926+0.258819<br>i\\(0.916667\\pi\\)
\\(620\\)00
\\(621\\)00
\\(622\\)00
\\(623\\)00
\\(624\\)00
\\(625\\)\u22120.500000\u22120.866025<br>i\u22120.500000\u22120.866025<br>i
\\(626\\)\u22120.366025\u22121.36603<br>i\u22120.366025\u22121.36603<br>i
\\(627\\)00
\\(628\\)\u22121.00000\u22121.73205<br>i\u22121.00000\u22121.73205<br>i
\\(629\\)\u22121.00000+1.00000<br>i\u22121.00000+1.00000<br>i
\\(630\\)00
\\(631\\)00\u22121.00000<br>i\\(-0.5\\pi\\)
1.00000<br>i\\(0.5\\pi\\)
\\(632\\)00
\\(633\\)00
\\(634\\)0.366025+1.36603<br>i0.366025+1.36603<br>i
\\(635\\)00
\\(636\\)00
\\(637\\)00
\\(638\\)00
\\(639\\)00
\\(640\\)\u22121.36603+0.366025<br>i\u22121.36603+0.366025<br>i
\\(641\\)\u22120.366025\u22121.36603<br>i\u22120.366025\u22121.36603<br>i\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
0.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
\\(642\\)00
\\(643\\)000.707107\u22120.707107<br>i\\(-0.250000\\pi\\)
\u22120.707107+0.707107<br>i\\(0.750000\\pi\\)
\\(644\\)00
\\(645\\)00
\\(646\\)00
\\(647\\)000.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
\u22120.500000+0.866025<br>i\\(0.666667\\pi\\)
\\(648\\)0.866025+0.500000<br>i0.866025+0.500000<br>i
\\(649\\)00
\\(650\\)00
\\(651\\)00
\\(652\\)00
\\(653\\)0.366025\u22121.36603<br>i0.366025\u22121.36603<br>i\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
0.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
\\(654\\)00
\\(655\\)00
\\(656\\)\u22120.366025+1.36603<br>i\u22120.366025+1.36603<br>i
\\(657\\)1.00000+1.00000<br>i1.00000+1.00000<br>i
\\(658\\)00
\\(659\\)001.00000\\(0\\)
\u22121.00000\\(\\pi\\)
\\(660\\)00
\\(661\\)000.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
\u22120.500000+0.866025<br>i\\(0.666667\\pi\\)
\\(662\\)00
\\(663\\)00
\\(664\\)00
\\(665\\)00
\\(666\\)1.00000\u22121.00000<br>i1.00000\u22121.00000<br>i
\\(667\\)00
\\(668\\)00
\\(669\\)00
\\(670\\)00
\\(671\\)00
\\(672\\)00
\\(673\\)\u22121.00000\u22121.00000<br>i\u22121.00000\u22121.00000<br>i\u22121.00000<br>i\\(-0.5\\pi\\)
\u22121.00000\\(\\pi\\)
\\(674\\)\u22120.366025+1.36603<br>i\u22120.366025+1.36603<br>i
\\(675\\)00
\\(676\\)\u22120.500000+0.866025<br>i\u22120.500000+0.866025<br>i
\\(677\\)1.36603+0.366025<br>i1.36603+0.366025<br>i0.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
0.500000+0.866025<br>i\\(0.333333\\pi\\)
\\(678\\)00
\\(679\\)00
\\(680\\)1.00000+1.00000<br>i1.00000+1.00000<br>i
\\(681\\)00
\\(682\\)00
\\(683\\)00\u22120.258819\u22120.965926<br>i\\(-0.583333\\pi\\)
0.258819+0.965926<br>i\\(0.416667\\pi\\)
\\(684\\)00
\\(685\\)00
\\(686\\)00
\\(687\\)00
\\(688\\)00
\\(689\\)00
\\(690\\)00
\\(691\\)000.258819\u22120.965926<br>i\\(-0.416667\\pi\\)
\u22120.258819+0.965926<br>i\\(0.583333\\pi\\)
\\(692\\)1.00000\u22121.00000<br>i1.00000\u22121.00000<br>i
\\(693\\)00
\\(694\\)00
\\(695\\)00
\\(696\\)00
\\(697\\)1.36603\u22120.366025<br>i1.36603\u22120.366025<br>i
\\(698\\)00
\\(699\\)00
\\(700\\)00
\\(701\\)00\u22121.00000<br>i\\(-0.5\\pi\\)
1.00000<br>i\\(0.5\\pi\\)
\\(702\\)00
\\(703\\)00
\\(704\\)00
\\(705\\)00
\\(706\\)\u22122.00000<br>i\u22122.00000<br>i
\\(707\\)00
\\(708\\)00
\\(709\\)\u22121.36603\u22120.366025<br>i\u22121.36603\u22120.366025<br>i\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(710\\)00
\\(711\\)00
\\(712\\)00
\\(713\\)00
\\(714\\)00
\\(715\\)00
\\(716\\)00
\\(717\\)00
\\(718\\)00
\\(719\\)00\u22120.965926\u22120.258819<br>i\\(-0.916667\\pi\\)
0.965926+0.258819<br>i\\(0.0833333\\pi\\)
\\(720\\)\u22121.00000\u22121.00000<br>i\u22121.00000\u22121.00000<br>i
\\(721\\)00
\\(722\\)1.00000<br>i1.00000<br>i
\\(723\\)00
\\(724\\)1.36603\u22120.366025<br>i1.36603\u22120.366025<br>i
\\(725\\)1.36603\u22120.366025<br>i1.36603\u22120.366025<br>i
\\(726\\)00
\\(727\\)001.00000\\(0\\)
\u22121.00000\\(\\pi\\)
\\(728\\)00
\\(729\\)1.00000<br>i1.00000<br>i
\\(730\\)\u22121.00000\u22121.73205<br>i\u22121.00000\u22121.73205<br>i
\\(731\\)00
\\(732\\)00
\\(733\\)00\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
0.500000+0.866025<br>i\\(0.333333\\pi\\)
\\(734\\)00
\\(735\\)00
\\(736\\)00
\\(737\\)00
\\(738\\)\u22121.36603+0.366025<br>i\u22121.36603+0.366025<br>i
\\(739\\)00\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
0.866025+0.500000<br>i\\(0.166667\\pi\\)
\\(740\\)\u22121.73205+1.00000<br>i\u22121.73205+1.00000<br>i
\\(741\\)00
\\(742\\)00
\\(743\\)000.707107\u22120.707107<br>i\\(-0.250000\\pi\\)
\u22120.707107+0.707107<br>i\\(0.750000\\pi\\)
\\(744\\)00
\\(745\\)0.732051+2.73205<br>i0.732051+2.73205<br>i
\\(746\\)00
\\(747\\)00
\\(748\\)00
\\(749\\)00
\\(750\\)00
\\(751\\)00\u22120.965926\u22120.258819<br>i\\(-0.916667\\pi\\)
0.965926+0.258819<br>i\\(0.0833333\\pi\\)
\\(752\\)00
\\(753\\)00
\\(754\\)00
\\(755\\)00
\\(756\\)00
\\(757\\)2.00000<br>i2.00000<br>i1.00000<br>i\\(0.5\\pi\\)
1.00000<br>i\\(0.5\\pi\\)
\\(758\\)00
\\(759\\)00
\\(760\\)00
\\(761\\)000.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(762\\)00
\\(763\\)00
\\(764\\)00
\\(765\\)\u22120.366025+1.36603<br>i\u22120.366025+1.36603<br>i
\\(766\\)00
\\(767\\)00
\\(768\\)00
\\(769\\)00\u22121.00000<br>i\\(-0.5\\pi\\)
1.00000<br>i\\(0.5\\pi\\)
\\(770\\)00
\\(771\\)00
\\(772\\)\u22120.366025+1.36603<br>i\u22120.366025+1.36603<br>i
\\(773\\)\u22121.73205\u22121.00000<br>i\u22121.73205\u22121.00000<br>i\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
\u22120.866025\u22120.500000<br>i\\(-0.833333\\pi\\)
\\(774\\)00
\\(775\\)00
\\(776\\)1.00000+1.00000<br>i1.00000+1.00000<br>i
\\(777\\)00
\\(778\\)2.000002.00000
\\(779\\)00
\\(780\\)00
\\(781\\)00
\\(782\\)00
\\(783\\)00
\\(784\\)00
\\(785\\)\u22122.00000+2.00000<br>i\u22122.00000+2.00000<br>i
\\(786\\)00
\\(787\\)00\u22120.258819\u22120.965926<br>i\\(-0.583333\\pi\\)
0.258819+0.965926<br>i\\(0.416667\\pi\\)
\\(788\\)1.36603\u22120.366025<br>i1.36603\u22120.366025<br>i
\\(789\\)00
\\(790\\)00
\\(791\\)00
\\(792\\)00
\\(793\\)00
\\(794\\)0.366025+1.36603<br>i0.366025+1.36603<br>i
\\(795\\)00
\\(796\\)00
\\(797\\)001.00000\\(0\\)
\u22121.00000\\(\\pi\\)
\\(798\\)00
\\(799\\)00
\\(800\\)0.500000+0.866025<br>i0.500000+0.866025<br>i
\\(801\\)00
\\(802\\)0.366025+1.36603<br>i0.366025+1.36603<br>i
\\(803\\)00
\\(804\\)00
\\(805\\)00
\\(806\\)00
\\(807\\)00
\\(808\\)00
\\(809\\)1.36603\u22120.366025<br>i1.36603\u22120.366025<br>i0.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
0.866025+0.500000<br>i\\(0.166667\\pi\\)
\\(810\\)0.366025\u22121.36603<br>i0.366025\u22121.36603<br>i
\\(811\\)000.707107\u22120.707107<br>i\\(-0.250000\\pi\\)
\u22120.707107+0.707107<br>i\\(0.750000\\pi\\)
\\(812\\)00
\\(813\\)00
\\(814\\)00
\\(815\\)00
\\(816\\)00
\\(817\\)00
\\(818\\)\u22122.00000<br>i\u22122.00000<br>i
\\(819\\)00
\\(820\\)2.000002.00000
\\(821\\)\u22121.36603\u22120.366025<br>i\u22121.36603\u22120.366025<br>i\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(822\\)00
\\(823\\)000.965926\u22120.258819<br>i\\(-0.0833333\\pi\\)
\u22120.965926+0.258819<br>i\\(0.916667\\pi\\)
\\(824\\)00
\\(825\\)00
\\(826\\)00
\\(827\\)00\u22120.707107\u22120.707107<br>i\\(-0.750000\\pi\\)
0.707107+0.707107<br>i\\(0.250000\\pi\\)
\\(828\\)00
\\(829\\)1.00000\u22121.73205<br>i1.00000\u22121.73205<br>i0.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
0.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
\\(830\\)00
\\(831\\)00
\\(832\\)00
\\(833\\)00
\\(834\\)00
\\(835\\)00
\\(836\\)00
\\(837\\)00
\\(838\\)00
\\(839\\)00\u22120.707107\u22120.707107<br>i\\(-0.750000\\pi\\)
0.707107+0.707107<br>i\\(0.250000\\pi\\)
\\(840\\)00
\\(841\\)\u22121.00000<br>i\u22121.00000<br>i
\\(842\\)00
\\(843\\)00
\\(844\\)00
\\(845\\)1.36603+0.366025<br>i1.36603+0.366025<br>i
\\(846\\)00
\\(847\\)00
\\(848\\)00
\\(849\\)00
\\(850\\)0.500000\u22120.866025<br>i0.500000\u22120.866025<br>i
\\(851\\)00
\\(852\\)00
\\(853\\)1.00000\u22121.00000<br>i1.00000\u22121.00000<br>i\u22121.00000<br>i\\(-0.5\\pi\\)
1.00000\\(0\\)
\\(854\\)00
\\(855\\)00
\\(856\\)00
\\(857\\)1.36603\u22120.366025<br>i1.36603\u22120.366025<br>i0.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
0.866025+0.500000<br>i\\(0.166667\\pi\\)
\\(858\\)00
\\(859\\)000.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(860\\)00
\\(861\\)00
\\(862\\)00
\\(863\\)00\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
0.500000+0.866025<br>i\\(0.333333\\pi\\)
\\(864\\)00
\\(865\\)\u22121.73205\u22121.00000<br>i\u22121.73205\u22121.00000<br>i
\\(866\\)\u22121.00000\u22121.73205<br>i\u22121.00000\u22121.73205<br>i
\\(867\\)00
\\(868\\)00
\\(869\\)00
\\(870\\)00
\\(871\\)00
\\(872\\)0.366025+1.36603<br>i0.366025+1.36603<br>i
\\(873\\)\u22120.366025+1.36603<br>i\u22120.366025+1.36603<br>i
\\(874\\)00
\\(875\\)00
\\(876\\)00
\\(877\\)\u22120.366025+1.36603<br>i\u22120.366025+1.36603<br>i0.500000+0.866025<br>i\\(0.333333\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(878\\)00
\\(879\\)00
\\(880\\)00
\\(881\\)\u22121.00000+1.00000<br>i\u22121.00000+1.00000<br>i1.00000<br>i\\(0.5\\pi\\)
\u22121.00000\\(\\pi\\)
\\(882\\)00
\\(883\\)001.00000\\(0\\)
\u22121.00000\\(\\pi\\)
\\(884\\)00
\\(885\\)00
\\(886\\)00
\\(887\\)00\u22120.965926\u22120.258819<br>i\\(-0.916667\\pi\\)
0.965926+0.258819<br>i\\(0.0833333\\pi\\)
\\(888\\)00
\\(889\\)00
\\(890\\)00
\\(891\\)00
\\(892\\)00
\\(893\\)00
\\(894\\)00
\\(895\\)00
\\(896\\)00
\\(897\\)00
\\(898\\)1.36603+0.366025<br>i1.36603+0.366025<br>i
\\(899\\)00
\\(900\\)\u22120.500000+0.866025<br>i\u22120.500000+0.866025<br>i
\\(901\\)00
\\(902\\)00
\\(903\\)00
\\(904\\)1.00000\u22121.00000<br>i1.00000\u22121.00000<br>i
\\(905\\)\u22121.00000\u22121.73205<br>i\u22121.00000\u22121.73205<br>i
\\(906\\)00
\\(907\\)000.965926\u22120.258819<br>i\\(-0.0833333\\pi\\)
\u22120.965926+0.258819<br>i\\(0.916667\\pi\\)
\\(908\\)00
\\(909\\)00
\\(910\\)00
\\(911\\)00\u22120.707107\u22120.707107<br>i\\(-0.750000\\pi\\)
0.707107+0.707107<br>i\\(0.250000\\pi\\)
\\(912\\)00
\\(913\\)00
\\(914\\)1.00000\u22121.73205<br>i1.00000\u22121.73205<br>i
\\(915\\)00
\\(916\\)2.00000<br>i2.00000<br>i
\\(917\\)00
\\(918\\)00
\\(919\\)00\u22120.500000\u22120.866025<br>i\\(-0.666667\\pi\\)
0.500000+0.866025<br>i\\(0.333333\\pi\\)
\\(920\\)00
\\(921\\)00
\\(922\\)00
\\(923\\)00
\\(924\\)00
\\(925\\)1.00000+1.00000<br>i1.00000+1.00000<br>i
\\(926\\)00
\\(927\\)00
\\(928\\)1.36603\u22120.366025<br>i1.36603\u22120.366025<br>i
\\(929\\)\u22120.366025+1.36603<br>i\u22120.366025+1.36603<br>i0.500000+0.866025<br>i\\(0.333333\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(930\\)00
\\(931\\)00
\\(932\\)1.00000\u22121.00000<br>i1.00000\u22121.00000<br>i
\\(933\\)00
\\(934\\)00
\\(935\\)00
\\(936\\)00
\\(937\\)001.00000\\(0\\)
\u22121.00000\\(\\pi\\)
\\(938\\)00
\\(939\\)00
\\(940\\)00
\\(941\\)1.36603\u22120.366025<br>i1.36603\u22120.366025<br>i0.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
0.866025+0.500000<br>i\\(0.166667\\pi\\)
\\(942\\)00
\\(943\\)00
\\(944\\)00
\\(945\\)00
\\(946\\)00
\\(947\\)00\u22120.965926\u22120.258819<br>i\\(-0.916667\\pi\\)
0.965926+0.258819<br>i\\(0.0833333\\pi\\)
\\(948\\)00
\\(949\\)00
\\(950\\)00
\\(951\\)00
\\(952\\)00
\\(953\\)00\u22121.00000<br>i\\(-0.5\\pi\\)
1.00000<br>i\\(0.5\\pi\\)
\\(954\\)00
\\(955\\)00
\\(956\\)00
\\(957\\)00
\\(958\\)00
\\(959\\)00
\\(960\\)00
\\(961\\)\u22120.866025+0.500000<br>i\u22120.866025+0.500000<br>i
\\(962\\)00
\\(963\\)00
\\(964\\)\u22121.36603\u22120.366025<br>i\u22121.36603\u22120.366025<br>i
\\(965\\)2.000002.00000
\\(966\\)00
\\(967\\)00\u22121.00000<br>i\\(-0.5\\pi\\)
1.00000<br>i\\(0.5\\pi\\)
\\(968\\)0.500000+0.866025<br>i0.500000+0.866025<br>i
\\(969\\)00
\\(970\\)1.00000\u22121.73205<br>i1.00000\u22121.73205<br>i
\\(971\\)000.866025\u22120.500000<br>i\\(-0.166667\\pi\\)
\u22120.866025+0.500000<br>i\\(0.833333\\pi\\)
\\(972\\)00
\\(973\\)00
\\(974\\)00
\\(975\\)00
\\(976\\)\u22121.36603+0.366025<br>i\u22121.36603+0.366025<br>i
\\(977\\)000.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
\u22120.500000+0.866025<br>i\\(0.666667\\pi\\)
\\(978\\)00
\\(979\\)00
\\(980\\)00
\\(981\\)\u22121.00000+1.00000<br>i\u22121.00000+1.00000<br>i
\\(982\\)00
\\(983\\)00\u22120.258819\u22120.965926<br>i\\(-0.583333\\pi\\)
0.258819+0.965926<br>i\\(0.416667\\pi\\)
\\(984\\)00
\\(985\\)\u22121.00000\u22121.73205<br>i\u22121.00000\u22121.73205<br>i
\\(986\\)\u22121.00000\u22121.00000<br>i\u22121.00000\u22121.00000<br>i
\\(987\\)00
\\(988\\)00
\\(989\\)00
\\(990\\)00
\\(991\\)00\u22120.258819\u22120.965926<br>i\\(-0.583333\\pi\\)
0.258819+0.965926<br>i\\(0.416667\\pi\\)
\\(992\\)00
\\(993\\)00
\\(994\\)00
\\(995\\)00
\\(996\\)00
\\(997\\)1.36603\u22120.366025<br>i1.36603\u22120.366025<br>i0.500000\u22120.866025<br>i\\(-0.333333\\pi\\)
0.866025+0.500000<br>i\\(0.166667\\pi\\)
\\(998\\)00
\\(999\\)00
\n\n( See \\(a_n\\) instead)\n\n( See \\(a_n\\) instead)\n\n( See \\(a_n\\) instead)\n\n( See only \\(a_p\\))\n\n( See only \\(a_p\\))\n\n( See only \\(a_p\\))\n\n
By<br>twisting character
CharParityOrdTypeTwistMinDim
1.1even1trivial3332.1.bc.b.2027.14
4.3odd2CM3332.1.bc.b.2027.14
7.2even3inner3332.1.bc.b.667.14
7.3odd668.1.f.a.55.1yes2
7.4even33332.1.m.b.2843.12
7.5odd63332.1.bc.c.667.14
7.6odd23332.1.bc.c.2027.14
17.13even4inner3332.1.bc.b.2223.14
21.17even6612.1.l.a.55.12
28.3even668.1.f.a.55.1yes2
28.11odd63332.1.m.b.2843.12
28.19even63332.1.bc.c.667.14
28.23odd6inner3332.1.bc.b.667.14
28.27even23332.1.bc.c.2027.14
35.3even121700.1.n.a.599.12
35.17even121700.1.n.b.599.12
35.24odd61700.1.p.a.1551.12
56.3even61088.1.p.a.191.12
56.45odd61088.1.p.a.191.12
68.47odd4inner3332.1.bc.b.2223.14
84.59odd6612.1.l.a.55.12
119.3even481156.1.g.b.155.18
119.10even481156.1.g.b.179.18
119.13odd43332.1.bc.c.2223.14
119.24even481156.1.g.b.179.28
119.30even12inner3332.1.bc.b.863.14
119.31even481156.1.g.b.155.28
119.38odd121156.1.f.b.251.12
119.45even481156.1.g.b.399.18
119.47odd123332.1.bc.c.863.14
119.59odd241156.1.c.b.579.12
119.66odd241156.1.d.a.1155.22
119.73even481156.1.g.b.423.28
119.80even481156.1.g.b.423.18
119.81even123332.1.m.b.3039.12
119.87odd241156.1.d.a.1155.12
119.94odd241156.1.c.b.579.22
119.101odd61156.1.f.b.327.12
119.108even481156.1.g.b.399.28
119.115odd1268.1.f.a.47.1&check;2
140.3odd121700.1.n.a.599.12
140.59even61700.1.p.a.1551.12
140.87odd121700.1.n.b.599.12
357.353even12612.1.l.a.523.12
476.3odd481156.1.g.b.155.18
476.31odd481156.1.g.b.155.28
476.47even123332.1.bc.c.863.14
476.59even241156.1.c.b.579.12
476.87even241156.1.d.a.1155.12
476.115even1268.1.f.a.47.1&check;2
476.143odd481156.1.g.b.179.28
476.199odd481156.1.g.b.423.18
476.227odd481156.1.g.b.399.28
476.251even43332.1.bc.c.2223.14
476.283odd481156.1.g.b.399.18
476.311odd481156.1.g.b.423.28
476.319odd123332.1.m.b.3039.12
476.339even61156.1.f.b.327.12
476.367odd481156.1.g.b.179.18
476.387odd12inner3332.1.bc.b.863.14
476.395even121156.1.f.b.251.12
476.423even241156.1.d.a.1155.22
476.451even241156.1.c.b.579.22
595.234odd121700.1.p.a.251.12
595.353even121700.1.n.b.999.12
595.472even121700.1.n.a.999.12
952.115even121088.1.p.a.319.12
952.829odd121088.1.p.a.319.12
1428.1067odd12612.1.l.a.523.12
2380.1067odd121700.1.n.a.999.12
2380.1543odd121700.1.n.b.999.12
2380.2019even121700.1.p.a.251.12
\n\n
By<br>twisted newform
TwistMinDimCharParityOrdType
68.1.f.a.47.1&check;2119.115odd12
68.1.f.a.47.1&check;2476.115even12
68.1.f.a.55.1yes27.3odd6
68.1.f.a.55.1yes228.3even6
612.1.l.a.55.1221.17even6
612.1.l.a.55.1284.59odd6
612.1.l.a.523.12357.353even12
612.1.l.a.523.121428.1067odd12
1088.1.p.a.191.1256.3even6
1088.1.p.a.191.1256.45odd6
1088.1.p.a.319.12952.115even12
1088.1.p.a.319.12952.829odd12
1156.1.c.b.579.12119.59odd24
1156.1.c.b.579.12476.59even24
1156.1.c.b.579.22119.94odd24
1156.1.c.b.579.22476.451even24
1156.1.d.a.1155.12119.87odd24
1156.1.d.a.1155.12476.87even24
1156.1.d.a.1155.22119.66odd24
1156.1.d.a.1155.22476.423even24
1156.1.f.b.251.12119.38odd12
1156.1.f.b.251.12476.395even12
1156.1.f.b.327.12119.101odd6
1156.1.f.b.327.12476.339even6
1156.1.g.b.155.18119.3even48
1156.1.g.b.155.18476.3odd48
1156.1.g.b.155.28119.31even48
1156.1.g.b.155.28476.31odd48
1156.1.g.b.179.18119.10even48
1156.1.g.b.179.18476.367odd48
1156.1.g.b.179.28119.24even48
1156.1.g.b.179.28476.143odd48
1156.1.g.b.399.18119.45even48
1156.1.g.b.399.18476.283odd48
1156.1.g.b.399.28119.108even48
1156.1.g.b.399.28476.227odd48
1156.1.g.b.423.18119.80even48
1156.1.g.b.423.18476.199odd48
1156.1.g.b.423.28119.73even48
1156.1.g.b.423.28476.311odd48
1700.1.n.a.599.1235.3even12
1700.1.n.a.599.12140.3odd12
1700.1.n.a.999.12595.472even12
1700.1.n.a.999.122380.1067odd12
1700.1.n.b.599.1235.17even12
1700.1.n.b.599.12140.87odd12
1700.1.n.b.999.12595.353even12
1700.1.n.b.999.122380.1543odd12
1700.1.p.a.251.12595.234odd12
1700.1.p.a.251.122380.2019even12
1700.1.p.a.1551.1235.24odd6
1700.1.p.a.1551.12140.59even6
3332.1.m.b.2843.127.4even3
3332.1.m.b.2843.1228.11odd6
3332.1.m.b.3039.12119.81even12
3332.1.m.b.3039.12476.319odd12
3332.1.bc.b.667.147.2even3inner
3332.1.bc.b.667.1428.23odd6inner
3332.1.bc.b.863.14119.30even12inner
3332.1.bc.b.863.14476.387odd12inner
3332.1.bc.b.2027.141.1even1trivial
3332.1.bc.b.2027.144.3odd2CM
3332.1.bc.b.2223.1417.13even4inner
3332.1.bc.b.2223.1468.47odd4inner
3332.1.bc.c.667.147.5odd6
3332.1.bc.c.667.1428.19even6
3332.1.bc.c.863.14119.47odd12
3332.1.bc.c.863.14476.47even12
3332.1.bc.c.2027.147.6odd2
3332.1.bc.c.2027.1428.27even2
3332.1.bc.c.2223.14119.13odd4
3332.1.bc.c.2223.14476.251even4
\n", "html": "\n\n\n \n \n \n \n LMFDB - Embedded newform 3332.1.bc.b.2027.1 \n \n\n \n \n \n \n \n\n \n \n\n\n\n\n \n\n \n \n\n \n \n\n\n \n \n \n \n \n \n\n\n\n\n\n \n \n\n
\n
\n \n
\n
\n
\n
\n \n → Modular forms\n → Classical\n → Level 3332\n → Weight 1\n → Character orbit bc\n → Newform orbit b\n → Embedding 2027.1\n
\n
\n \n
\n Citation\n ·\n Feedback\n ·\n Hide Menu\n \n
\n
\n\n
\n
Embedded newform 3332.1.bc.b.2027.1
\n\n
\n
\n\n
\n

Introduction

\n\n\n\n \n \n \n
OverviewRandom
UniverseKnowledge
\n\n\n\n

L-functions

\n\n\n\n \n \n \n
RationalAll
\n\n\n\n

Modular forms

\n\n\n\n \n \n \n
ClassicalMaass
HilbertBianchi
\n\n\n\n

Varieties

\n\n\n\n \n \n \n
Elliptic curves over $\\Q$
Elliptic curves over $\\Q(\\alpha)$
Genus 2 curves over $\\Q$
Higher genus families
Abelian varieties over $\\F_{q}$
\n\n\n\n

Fields

\n\n\n\n \n \n \n
Number fields
$p$-adic fields
\n\n\n\n

Representations

\n\n\n\n \n \n \n
Dirichlet characters
Artin representations
\n\n\n\n

Groups

\n\n\n\n \n \n \n
Galois groups
Sato-Tate groups
\n\n\n\n

Database

\n\n\n\n\n
\n\n\n\n
\n
\n

Properties

\n
\n \n
Label\n 3332.1.bc.b.2027.1
\n
Level\n $3332$
Weight\n $1$
Character\n 3332.2027
Analytic conductor\n $1.663$
Analytic rank\n $0$
Dimension\n $4$
Projective image\n $D_{4}$
CM discriminant\n -4
Inner twists\n $8$
\n
\n\n\n\n

Related objects

\n
\n \n
\n\n\n\n

Downloads

\n
\n \n
\n\n

Learn more

\n
\n \n
\n\n
\n
\n
\n
\n
\n \n
\n Show commands:\n Magma\n / PariGP\n / SageMath\n
\n\n\n\n\n

Newspace parameters

\n\n
comment: Compute space of new eigenforms
 
\n
[N,k,chi] = [3332,1,Mod(667,3332)]
 
mf = mfinit([N,k,chi],0)
 
lf = mfeigenbasis(mf)
 
\n
from sage.modular.dirichlet import DirichletCharacter
 
H = DirichletGroup(3332, base_ring=CyclotomicField(12))
 
chi = DirichletCharacter(H, H._module([6, 4, 9]))
 
N = Newforms(chi, 1, names="a")
 
\n
//Please install CHIMP (https://github.com/edgarcosta/CHIMP) if you want to run this code
 
chi := DirichletCharacter("3332.667");
 
S:= CuspForms(chi, 1);
 
N := Newforms(S);
 
\n\n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n
Level: \\( N \\) \\(=\\)\\( 3332 = 2^{2} \\cdot 7^{2} \\cdot 17 \\)
Weight: \\( k \\) \\(=\\)\\( 1 \\)
Character orbit: \\([\\chi]\\) \\(=\\) 3332.bc (of order \\(12\\), degree \\(4\\), not minimal)
\n\n

Newform invariants

\n\n
comment: select newform
 
\n
sage: f = N[0] # Warning: the index may be different
 
\n
gp: f = lf[1] \\\\ Warning: the index may be different
 
\n\n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\t\n \n \t\n \t\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n
Self dual: no
Analytic conductor: \\(1.66288462209\\)
Analytic rank: \\(0\\)
Dimension: \\(4\\)
Coefficient field: \\(\\Q(\\zeta_{12})\\)
\n
comment: defining polynomial
 
\n
gp: f.mod \\\\ as an extension of the character field
 
\n\n
Defining polynomial: \n\n \\( x^{4} - x^{2} + 1 \\)\n \n\n \n \"Copy\n \n \n \"Toggle\n \n
Coefficient ring: \\(\\Z[a_1, a_2]\\)
Coefficient ring index: \\( 1 \\)
Twist minimal: no (minimal twist has level 68)
Projective image:\\(D_{4}\\)
Projective field:Galois closure of 4.2.19652.1
Artin image:$C_4\\wr C_2\\times C_6$
Artin field:Galois closure of \\(\\mathbb{Q}[x]/(x^{48} - \\cdots)\\)
\n\n\n

Embedding invariants

\n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n
Embedding label 2027.1
Root\\(0.866025 - 0.500000i\\) of defining polynomial
Character\\(\\chi\\)\\(=\\)3332.2027
Dual form 3332.1.bc.b.863.1
\n\n\n

$q$-expansion

\n
\n
comment: q-expansion
 
\n
sage: f.q_expansion() # note that sage often uses an isomorphic number field
 
\n
gp: mfcoefs(f, 20)
 
\n\n
\n \n \n \n \n \n \n \n \n \n \n \n
\\(f(q)\\)\\(=\\)\\(q+(-0.866025 + 0.500000i) q^{2} +(0.500000 - 0.866025i) q^{4} +(-1.36603 - 0.366025i) q^{5} +1.00000i q^{8} +(-0.866025 + 0.500000i) q^{9} +(1.36603 - 0.366025i) q^{10} +(-0.500000 - 0.866025i) q^{16} +(-0.500000 + 0.866025i) q^{17} +(0.500000 - 0.866025i) q^{18} +(-1.00000 + 1.00000i) q^{20} +(0.866025 + 0.500000i) q^{25} +(1.00000 - 1.00000i) q^{29} +(0.866025 + 0.500000i) q^{32} -1.00000i q^{34} +1.00000i q^{36} +(1.36603 + 0.366025i) q^{37} +(0.366025 - 1.36603i) q^{40} +(-1.00000 - 1.00000i) q^{41} +(1.36603 - 0.366025i) q^{45} -1.00000 q^{50} +(-0.366025 + 1.36603i) q^{58} +(0.366025 - 1.36603i) q^{61} -1.00000 q^{64} +(0.500000 + 0.866025i) q^{68} +(-0.500000 - 0.866025i) q^{72} +(-0.366025 - 1.36603i) q^{73} +(-1.36603 + 0.366025i) q^{74} +(0.366025 + 1.36603i) q^{80} +(0.500000 - 0.866025i) q^{81} +(1.36603 + 0.366025i) q^{82} +(1.00000 - 1.00000i) q^{85} +(-1.00000 + 1.00000i) q^{90} +(1.00000 - 1.00000i) q^{97} +O(q^{100})\\)
\\(\\operatorname{Tr}(f)(q)\\)\\(=\\)\n\n \\( 4 q + 2 q^{4} - 2 q^{5} + 2 q^{10} - 2 q^{16} - 2 q^{17} + 2 q^{18} - 4 q^{20} + 4 q^{29} + 2 q^{37} - 2 q^{40} - 4 q^{41} + 2 q^{45} - 4 q^{50} + 2 q^{58} - 2 q^{61} - 4 q^{64} + 2 q^{68} - 2 q^{72} + 2 q^{73}+ \\cdots + 4 q^{97}+O(q^{100}) \\)\n \n\n \n \"Copy\n \n \n \"Toggle\n \n
\n
\n\n
\n\n\n

Character values

\n

We give the values of \\(\\chi\\) on generators for \\(\\left(\\mathbb{Z}/3332\\mathbb{Z}\\right)^\\times\\).

\n\n \n \n \n \n \n \n \n \n \n \n \n \n
\\(n\\)\\(785\\)\\(885\\)\\(1667\\)
\\(\\chi(n)\\)\\(e\\left(\\frac{3}{4}\\right)\\)\\(e\\left(\\frac{2}{3}\\right)\\)\\(-1\\)
\n\n\n

Coefficient data

\n\n

For each \\(n\\) we display the coefficients of the \\(q\\)-expansion \\(a_n\\), the\nSatake parameters \\(\\alpha_p\\),\nand the Satake angles \\(\\theta_p = \\textrm{Arg}(\\alpha_p)\\).

\n\n\n\n\n

\n
\n \n Display \\(a_p\\) with \\(p\\) up to:\n 50\n 250\n 1000\n \n\n \n (See \\(a_n\\) instead)\n \n\n \n (See \\(a_n\\) instead)\n \n\n \n (See \\(a_n\\) instead)\n \n \n Display \\(a_n\\) with \\(n\\) up to:\n 50\n 250\n 1000\n \n\n \n (See only \\(a_p\\))\n \n\n \n (See only \\(a_p\\))\n \n\n \n (See only \\(a_p\\))\n \n
\n\n\n
\n \n \n \n \n \n \n
Significant digits:
\n
\n\n
\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n 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\n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n
\n \\(n\\)\n \n \\(a_n\\)\n \n \\(a_n / n^{(k-1)/2}\\)\n \n \\( \\alpha_n \\)\n \n \\( \\theta_n \\)\n
\n \\(p\\)\n \n \\(a_p\\)\n \n \\(a_p / p^{(k-1)/2}\\)\n \n \\( \\alpha_p\\)\n \n \\( \\theta_p \\)\n
\n \\(2\\)\n \n −0.866025\n \n +\n \n 0.500000i\n \n −0.866025\n \n +\n \n 0.500000i\n \n\n \n\n \n\n \n\n
\n\n \n\n \n\n \n\n
\n \\(3\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.258819\n \n −\n \n 0.965926i\n \n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \n \\(0.416667\\pi\\)\n
\n \\(4\\)\n \n 0.500000\n \n −\n \n 0.866025i\n \n 0.500000\n \n −\n \n 0.866025i\n
\n \\(5\\)\n \n −1.36603\n \n −\n \n 0.366025i\n \n −1.36603\n \n −\n \n 0.366025i\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(6\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(7\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n\n \n\n \n\n
\n\n \n\n \n\n \n\n
\n \\(8\\)\n \n\n \n\n \n 1.00000i\n \n\n \n\n \n 1.00000i\n
\n \\(9\\)\n \n −0.866025\n \n +\n \n 0.500000i\n \n −0.866025\n \n +\n \n 0.500000i\n
\n \\(10\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n
\n \\(11\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.965926\n \n −\n \n 0.258819i\n \n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \n \\(0.916667\\pi\\)\n
\n \\(12\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(13\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(14\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(15\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(16\\)\n \n −0.500000\n \n −\n \n 0.866025i\n \n −0.500000\n \n −\n \n 0.866025i\n
\n \\(17\\)\n \n −0.500000\n \n +\n \n 0.866025i\n \n −0.500000\n \n +\n \n 0.866025i\n \n\n \n\n \n\n \n\n
\n\n \n\n \n\n \n\n
\n \\(18\\)\n \n 0.500000\n \n −\n \n 0.866025i\n \n 0.500000\n \n −\n \n 0.866025i\n
\n \\(19\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(20\\)\n \n −1.00000\n \n +\n \n 1.00000i\n \n −1.00000\n \n +\n \n 1.00000i\n
\n \\(21\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(22\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(23\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.258819\n \n −\n \n 0.965926i\n \n \\(-0.416667\\pi\\)\n
\n −0.258819\n \n +\n \n 0.965926i\n \n \\(0.583333\\pi\\)\n
\n \\(24\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(25\\)\n \n 0.866025\n \n +\n \n 0.500000i\n \n 0.866025\n \n +\n \n 0.500000i\n
\n \\(26\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(27\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(28\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(29\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n \\(30\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(31\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.258819\n \n −\n \n 0.965926i\n \n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \n \\(0.416667\\pi\\)\n
\n \\(32\\)\n \n 0.866025\n \n +\n \n 0.500000i\n \n 0.866025\n \n +\n \n 0.500000i\n
\n \\(33\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(34\\)\n \n\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n
\n \\(35\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(36\\)\n \n\n \n\n \n 1.00000i\n \n\n \n\n \n 1.00000i\n
\n \\(37\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(38\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(39\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(40\\)\n \n 0.366025\n \n −\n \n 1.36603i\n \n 0.366025\n \n −\n \n 1.36603i\n
\n \\(41\\)\n \n −1.00000\n \n −\n \n 1.00000i\n \n −1.00000\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(42\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(43\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(44\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(45\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n
\n \\(46\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(47\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(48\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(49\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(50\\)\n \n −1.00000\n \n\n \n\n \n −1.00000\n \n\n \n\n
\n \\(51\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(52\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(53\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(54\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(55\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(56\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(57\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(58\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n
\n \\(59\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(60\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(61\\)\n \n 0.366025\n \n −\n \n 1.36603i\n \n 0.366025\n \n −\n \n 1.36603i\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n \\(62\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(63\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(64\\)\n \n −1.00000\n \n\n \n\n \n −1.00000\n \n\n \n\n
\n \\(65\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(66\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(67\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(68\\)\n \n 0.500000\n \n +\n \n 0.866025i\n \n 0.500000\n \n +\n \n 0.866025i\n
\n \\(69\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(70\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(71\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.707107\n \n −\n \n 0.707107i\n \n \\(-0.250000\\pi\\)\n
\n −0.707107\n \n +\n \n 0.707107i\n \n \\(0.750000\\pi\\)\n
\n \\(72\\)\n \n −0.500000\n \n −\n \n 0.866025i\n \n −0.500000\n \n −\n \n 0.866025i\n
\n \\(73\\)\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n \\(74\\)\n \n −1.36603\n \n +\n \n 0.366025i\n \n −1.36603\n \n +\n \n 0.366025i\n
\n \\(75\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(76\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(77\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(78\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(79\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.258819\n \n −\n \n 0.965926i\n \n \\(-0.416667\\pi\\)\n
\n −0.258819\n \n +\n \n 0.965926i\n \n \\(0.583333\\pi\\)\n
\n \\(80\\)\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.366025\n \n +\n \n 1.36603i\n
\n \\(81\\)\n \n 0.500000\n \n −\n \n 0.866025i\n \n 0.500000\n \n −\n \n 0.866025i\n
\n \\(82\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n
\n \\(83\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(84\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(85\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n
\n \\(86\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(87\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(88\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(89\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(90\\)\n \n −1.00000\n \n +\n \n 1.00000i\n \n −1.00000\n \n +\n \n 1.00000i\n
\n \\(91\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(92\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(93\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(94\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(95\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(96\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(97\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n \\(98\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(99\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(100\\)\n \n 0.866025\n \n −\n \n 0.500000i\n \n 0.866025\n \n −\n \n 0.500000i\n
\n \\(101\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(102\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(103\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(104\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(105\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(106\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(107\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.965926\n \n −\n \n 0.258819i\n \n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \n \\(0.0833333\\pi\\)\n
\n \\(108\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(109\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(110\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(111\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(112\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(113\\)\n \n −1.00000\n \n −\n \n 1.00000i\n \n −1.00000\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(114\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(115\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(116\\)\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.366025\n \n −\n \n 1.36603i\n
\n \\(117\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(118\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(119\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(120\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(121\\)\n \n 0.866025\n \n −\n \n 0.500000i\n \n 0.866025\n \n −\n \n 0.500000i\n
\n \\(122\\)\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.366025\n \n +\n \n 1.36603i\n
\n \\(123\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(124\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(125\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(126\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(127\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(128\\)\n \n 0.866025\n \n −\n \n 0.500000i\n \n 0.866025\n \n −\n \n 0.500000i\n
\n \\(129\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(130\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(131\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.965926\n \n −\n \n 0.258819i\n \n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \n \\(0.0833333\\pi\\)\n
\n \\(132\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(133\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(134\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(135\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(136\\)\n \n −0.866025\n \n −\n \n 0.500000i\n \n −0.866025\n \n −\n \n 0.500000i\n
\n \\(137\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(138\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(139\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.707107\n \n −\n \n 0.707107i\n \n \\(-0.250000\\pi\\)\n
\n −0.707107\n \n +\n \n 0.707107i\n \n \\(0.750000\\pi\\)\n
\n \\(140\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(141\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(142\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(143\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(144\\)\n \n 0.866025\n \n +\n \n 0.500000i\n \n 0.866025\n \n +\n \n 0.500000i\n
\n \\(145\\)\n \n −1.73205\n \n +\n \n 1.00000i\n \n −1.73205\n \n +\n \n 1.00000i\n
\n \\(146\\)\n \n 1.00000\n \n +\n \n 1.00000i\n \n 1.00000\n \n +\n \n 1.00000i\n
\n \\(147\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(148\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n
\n \\(149\\)\n \n −1.00000\n \n −\n \n 1.73205i\n \n −1.00000\n \n −\n \n 1.73205i\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n \\(150\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(151\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(152\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(153\\)\n \n\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n
\n \\(154\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(155\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(156\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(157\\)\n \n 1.00000\n \n −\n \n 1.73205i\n \n 1.00000\n \n −\n \n 1.73205i\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n \\(158\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(159\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(160\\)\n \n −1.00000\n \n −\n \n 1.00000i\n \n −1.00000\n \n −\n \n 1.00000i\n
\n \\(161\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(162\\)\n \n\n \n\n \n 1.00000i\n \n\n \n\n \n 1.00000i\n
\n \\(163\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.258819\n \n −\n \n 0.965926i\n \n \\(-0.416667\\pi\\)\n
\n −0.258819\n \n +\n \n 0.965926i\n \n \\(0.583333\\pi\\)\n
\n \\(164\\)\n \n −1.36603\n \n +\n \n 0.366025i\n \n −1.36603\n \n +\n \n 0.366025i\n
\n \\(165\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(166\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(167\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.707107\n \n −\n \n 0.707107i\n \n \\(-0.250000\\pi\\)\n
\n −0.707107\n \n +\n \n 0.707107i\n \n \\(0.750000\\pi\\)\n
\n \\(168\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(169\\)\n \n −1.00000\n \n\n \n\n \n −1.00000\n \n\n \n\n
\n \\(170\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n
\n \\(171\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(172\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(173\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(174\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(175\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(176\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(177\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(178\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(179\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(180\\)\n \n 0.366025\n \n −\n \n 1.36603i\n \n 0.366025\n \n −\n \n 1.36603i\n
\n \\(181\\)\n \n 1.00000\n \n +\n \n 1.00000i\n \n 1.00000\n \n +\n \n 1.00000i\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(182\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(183\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(184\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(185\\)\n \n −1.73205\n \n −\n \n 1.00000i\n \n −1.73205\n \n −\n \n 1.00000i\n
\n \\(186\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(187\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(188\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(189\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(190\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(191\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(192\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(193\\)\n \n −1.36603\n \n +\n \n 0.366025i\n \n −1.36603\n \n +\n \n 0.366025i\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(194\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n
\n \\(195\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(196\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(197\\)\n \n 1.00000\n \n +\n \n 1.00000i\n \n 1.00000\n \n +\n \n 1.00000i\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(198\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(199\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.258819\n \n −\n \n 0.965926i\n \n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \n \\(0.416667\\pi\\)\n
\n \\(200\\)\n \n −0.500000\n \n +\n \n 0.866025i\n \n −0.500000\n \n +\n \n 0.866025i\n
\n \\(201\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(202\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(203\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(204\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(205\\)\n \n 1.00000\n \n +\n \n 1.73205i\n \n 1.00000\n \n +\n \n 1.73205i\n
\n \\(206\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(207\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(208\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(209\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(210\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(211\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.707107\n \n −\n \n 0.707107i\n \n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \n \\(0.250000\\pi\\)\n
\n \\(212\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(213\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(214\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(215\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(216\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(217\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(218\\)\n \n −1.00000\n \n +\n \n 1.00000i\n \n −1.00000\n \n +\n \n 1.00000i\n
\n \\(219\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(220\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(221\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(222\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(223\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(224\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(225\\)\n \n −1.00000\n \n\n \n\n \n −1.00000\n \n\n \n\n
\n \\(226\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n
\n \\(227\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.965926\n \n −\n \n 0.258819i\n \n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \n \\(0.916667\\pi\\)\n
\n \\(228\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(229\\)\n \n −1.73205\n \n +\n \n 1.00000i\n \n −1.73205\n \n +\n \n 1.00000i\n \n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(230\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(231\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(232\\)\n \n 1.00000\n \n +\n \n 1.00000i\n \n 1.00000\n \n +\n \n 1.00000i\n
\n \\(233\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(234\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(235\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(236\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(237\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(238\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(239\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(240\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(241\\)\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n \\(242\\)\n \n −0.500000\n \n +\n \n 0.866025i\n \n −0.500000\n \n +\n \n 0.866025i\n
\n \\(243\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(244\\)\n \n −1.00000\n \n −\n \n 1.00000i\n \n −1.00000\n \n −\n \n 1.00000i\n
\n \\(245\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(246\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(247\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(248\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(249\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(250\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(251\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(252\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(253\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(254\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(255\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(256\\)\n \n −0.500000\n \n +\n \n 0.866025i\n \n −0.500000\n \n +\n \n 0.866025i\n
\n \\(257\\)\n \n 1.73205\n \n −\n \n 1.00000i\n \n 1.73205\n \n −\n \n 1.00000i\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n \\(258\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(259\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(260\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(261\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n
\n \\(262\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(263\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(264\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(265\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(266\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(267\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(268\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(269\\)\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(270\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(271\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(272\\)\n \n 1.00000\n \n\n \n\n \n 1.00000\n \n\n \n\n
\n \\(273\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(274\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(275\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(276\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(277\\)\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(278\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(279\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(280\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(281\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(282\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(283\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.965926\n \n −\n \n 0.258819i\n \n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \n \\(0.916667\\pi\\)\n
\n \\(284\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(285\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(286\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(287\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(288\\)\n \n −1.00000\n \n\n \n\n \n −1.00000\n \n\n \n\n
\n \\(289\\)\n \n −0.500000\n \n −\n \n 0.866025i\n \n −0.500000\n \n −\n \n 0.866025i\n
\n \\(290\\)\n \n 1.00000\n \n −\n \n 1.73205i\n \n 1.00000\n \n −\n \n 1.73205i\n
\n \\(291\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(292\\)\n \n −1.36603\n \n −\n \n 0.366025i\n \n −1.36603\n \n −\n \n 0.366025i\n
\n \\(293\\)\n \n 2.00000\n \n\n \n\n \n 2.00000\n \n\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n \\(294\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(295\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(296\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n
\n \\(297\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(298\\)\n \n 1.73205\n \n +\n \n 1.00000i\n \n 1.73205\n \n +\n \n 1.00000i\n
\n \\(299\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(300\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(301\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(302\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(303\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(304\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(305\\)\n \n −1.00000\n \n +\n \n 1.73205i\n \n −1.00000\n \n +\n \n 1.73205i\n
\n \\(306\\)\n \n 0.500000\n \n +\n \n 0.866025i\n \n 0.500000\n \n +\n \n 0.866025i\n
\n \\(307\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(308\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(309\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(310\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(311\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.258819\n \n −\n \n 0.965926i\n \n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \n \\(0.416667\\pi\\)\n
\n \\(312\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(313\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n \n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(314\\)\n \n\n \n\n \n 2.00000i\n \n\n \n\n \n 2.00000i\n
\n \\(315\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(316\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(317\\)\n \n 0.366025\n \n −\n \n 1.36603i\n \n 0.366025\n \n −\n \n 1.36603i\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n \\(318\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(319\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(320\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n
\n \\(321\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(322\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(323\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(324\\)\n \n −0.500000\n \n −\n \n 0.866025i\n \n −0.500000\n \n −\n \n 0.866025i\n
\n \\(325\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(326\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(327\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(328\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n
\n \\(329\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(330\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(331\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(332\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(333\\)\n \n −1.36603\n \n +\n \n 0.366025i\n \n −1.36603\n \n +\n \n 0.366025i\n
\n \\(334\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(335\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(336\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(337\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n \\(338\\)\n \n 0.866025\n \n −\n \n 0.500000i\n \n 0.866025\n \n −\n \n 0.500000i\n
\n \\(339\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(340\\)\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.366025\n \n −\n \n 1.36603i\n
\n \\(341\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(342\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(343\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(344\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(345\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(346\\)\n \n −1.36603\n \n +\n \n 0.366025i\n \n −1.36603\n \n +\n \n 0.366025i\n
\n \\(347\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.965926\n \n −\n \n 0.258819i\n \n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \n \\(0.916667\\pi\\)\n
\n \\(348\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(349\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(350\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(351\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(352\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(353\\)\n \n −1.00000\n \n +\n \n 1.73205i\n \n −1.00000\n \n +\n \n 1.73205i\n \n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(354\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(355\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(356\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(357\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(358\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(359\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(360\\)\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.366025\n \n +\n \n 1.36603i\n
\n \\(361\\)\n \n 0.500000\n \n −\n \n 0.866025i\n \n 0.500000\n \n −\n \n 0.866025i\n
\n \\(362\\)\n \n −1.36603\n \n −\n \n 0.366025i\n \n −1.36603\n \n −\n \n 0.366025i\n
\n \\(363\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(364\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(365\\)\n \n\n \n\n \n 2.00000i\n \n\n \n\n \n 2.00000i\n
\n \\(366\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(367\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.965926\n \n −\n \n 0.258819i\n \n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \n \\(0.916667\\pi\\)\n
\n \\(368\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(369\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n
\n \\(370\\)\n \n 2.00000\n \n\n \n\n \n 2.00000\n \n\n \n\n
\n \\(371\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(372\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(373\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(374\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(375\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(376\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(377\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(378\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(379\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.707107\n \n −\n \n 0.707107i\n \n \\(-0.250000\\pi\\)\n
\n −0.707107\n \n +\n \n 0.707107i\n \n \\(0.750000\\pi\\)\n
\n \\(380\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(381\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(382\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(383\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(384\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(385\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(386\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n
\n \\(387\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(388\\)\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.366025\n \n −\n \n 1.36603i\n
\n \\(389\\)\n \n −1.73205\n \n −\n \n 1.00000i\n \n −1.73205\n \n −\n \n 1.00000i\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n \\(390\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(391\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(392\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(393\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(394\\)\n \n −1.36603\n \n −\n \n 0.366025i\n \n −1.36603\n \n −\n \n 0.366025i\n
\n \\(395\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(396\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(397\\)\n \n 0.366025\n \n −\n \n 1.36603i\n \n 0.366025\n \n −\n \n 1.36603i\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n \\(398\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(399\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(400\\)\n \n\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n
\n \\(401\\)\n \n 0.366025\n \n −\n \n 1.36603i\n \n 0.366025\n \n −\n \n 1.36603i\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n \\(402\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(403\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(404\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(405\\)\n \n −1.00000\n \n +\n \n 1.00000i\n \n −1.00000\n \n +\n \n 1.00000i\n
\n \\(406\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(407\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(408\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(409\\)\n \n −1.00000\n \n +\n \n 1.73205i\n \n −1.00000\n \n +\n \n 1.73205i\n \n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(410\\)\n \n −1.73205\n \n −\n \n 1.00000i\n \n −1.73205\n \n −\n \n 1.00000i\n
\n \\(411\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(412\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(413\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(414\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(415\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(416\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(417\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(418\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(419\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.707107\n \n −\n \n 0.707107i\n \n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \n \\(0.250000\\pi\\)\n
\n \\(420\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(421\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(422\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(423\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(424\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(425\\)\n \n −0.866025\n \n +\n \n 0.500000i\n \n −0.866025\n \n +\n \n 0.500000i\n
\n \\(426\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(427\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(428\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(429\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(430\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(431\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.965926\n \n −\n \n 0.258819i\n \n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \n \\(0.916667\\pi\\)\n
\n \\(432\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(433\\)\n \n\n \n\n \n 2.00000i\n \n\n \n\n \n 2.00000i\n \n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(434\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(435\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(436\\)\n \n 0.366025\n \n −\n \n 1.36603i\n \n 0.366025\n \n −\n \n 1.36603i\n
\n \\(437\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(438\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(439\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.965926\n \n −\n \n 0.258819i\n \n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \n \\(0.0833333\\pi\\)\n
\n \\(440\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(441\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(442\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(443\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(444\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(445\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(446\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(447\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(448\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(449\\)\n \n −1.00000\n \n −\n \n 1.00000i\n \n −1.00000\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(450\\)\n \n 0.866025\n \n −\n \n 0.500000i\n \n 0.866025\n \n −\n \n 0.500000i\n
\n \\(451\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(452\\)\n \n −1.36603\n \n +\n \n 0.366025i\n \n −1.36603\n \n +\n \n 0.366025i\n
\n \\(453\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(454\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(455\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(456\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(457\\)\n \n −1.73205\n \n +\n \n 1.00000i\n \n −1.73205\n \n +\n \n 1.00000i\n \n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(458\\)\n \n 1.00000\n \n −\n \n 1.73205i\n \n 1.00000\n \n −\n \n 1.73205i\n
\n \\(459\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(460\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(461\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(462\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(463\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(464\\)\n \n −1.36603\n \n −\n \n 0.366025i\n \n −1.36603\n \n −\n \n 0.366025i\n
\n \\(465\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(466\\)\n \n −1.36603\n \n +\n \n 0.366025i\n \n −1.36603\n \n +\n \n 0.366025i\n
\n \\(467\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(468\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(469\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(470\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(471\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(472\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(473\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(474\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(475\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(476\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(477\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(478\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(479\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.258819\n \n −\n \n 0.965926i\n \n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \n \\(0.416667\\pi\\)\n
\n \\(480\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(481\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(482\\)\n \n 1.00000\n \n +\n \n 1.00000i\n \n 1.00000\n \n +\n \n 1.00000i\n
\n \\(483\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(484\\)\n \n\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n
\n \\(485\\)\n \n −1.73205\n \n +\n \n 1.00000i\n \n −1.73205\n \n +\n \n 1.00000i\n
\n \\(486\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(487\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.965926\n \n −\n \n 0.258819i\n \n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \n \\(0.916667\\pi\\)\n
\n \\(488\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n
\n \\(489\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(490\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(491\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(492\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(493\\)\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.366025\n \n +\n \n 1.36603i\n
\n \\(494\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(495\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(496\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(497\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(498\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(499\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.258819\n \n −\n \n 0.965926i\n \n \\(-0.416667\\pi\\)\n
\n −0.258819\n \n +\n \n 0.965926i\n \n \\(0.583333\\pi\\)\n
\n \\(500\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(501\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(502\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(503\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.707107\n \n −\n \n 0.707107i\n \n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \n \\(0.250000\\pi\\)\n
\n \\(504\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(505\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(506\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(507\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(508\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(509\\)\n \n −1.00000\n \n −\n \n 1.73205i\n \n −1.00000\n \n −\n \n 1.73205i\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n \\(510\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(511\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(512\\)\n \n\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n
\n \\(513\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(514\\)\n \n −1.00000\n \n +\n \n 1.73205i\n \n −1.00000\n \n +\n \n 1.73205i\n
\n \\(515\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(516\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(517\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(518\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(519\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(520\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(521\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(522\\)\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.366025\n \n −\n \n 1.36603i\n
\n \\(523\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(524\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(525\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(526\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(527\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(528\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(529\\)\n \n −0.866025\n \n −\n \n 0.500000i\n \n −0.866025\n \n −\n \n 0.500000i\n
\n \\(530\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(531\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(532\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(533\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(534\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(535\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(536\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(537\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(538\\)\n \n −1.00000\n \n −\n \n 1.00000i\n \n −1.00000\n \n −\n \n 1.00000i\n
\n \\(539\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(540\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(541\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(542\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(543\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(544\\)\n \n −0.866025\n \n +\n \n 0.500000i\n \n −0.866025\n \n +\n \n 0.500000i\n
\n \\(545\\)\n \n −2.00000\n \n\n \n\n \n −2.00000\n \n\n \n\n
\n \\(546\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(547\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.707107\n \n −\n \n 0.707107i\n \n \\(-0.250000\\pi\\)\n
\n −0.707107\n \n +\n \n 0.707107i\n \n \\(0.750000\\pi\\)\n
\n \\(548\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(549\\)\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.366025\n \n +\n \n 1.36603i\n
\n \\(550\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(551\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(552\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(553\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(554\\)\n \n −1.00000\n \n −\n \n 1.00000i\n \n −1.00000\n \n −\n \n 1.00000i\n
\n \\(555\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(556\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(557\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(558\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(559\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(560\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(561\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(562\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(563\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(564\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(565\\)\n \n 1.00000\n \n +\n \n 1.73205i\n \n 1.00000\n \n +\n \n 1.73205i\n
\n \\(566\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(567\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(568\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(569\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(570\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(571\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.965926\n \n −\n \n 0.258819i\n \n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \n \\(0.916667\\pi\\)\n
\n \\(572\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(573\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(574\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(575\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(576\\)\n \n 0.866025\n \n −\n \n 0.500000i\n \n 0.866025\n \n −\n \n 0.500000i\n
\n \\(577\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(578\\)\n \n 0.866025\n \n +\n \n 0.500000i\n \n 0.866025\n \n +\n \n 0.500000i\n
\n \\(579\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(580\\)\n \n\n \n\n \n 2.00000i\n \n\n \n\n \n 2.00000i\n
\n \\(581\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(582\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(583\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(584\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n
\n \\(585\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(586\\)\n \n −1.73205\n \n +\n \n 1.00000i\n \n −1.73205\n \n +\n \n 1.00000i\n
\n \\(587\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(588\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(589\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(590\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(591\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(592\\)\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.366025\n \n −\n \n 1.36603i\n
\n \\(593\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(594\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(595\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(596\\)\n \n −2.00000\n \n\n \n\n \n −2.00000\n \n\n \n\n
\n \\(597\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(598\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(599\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(600\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(601\\)\n \n −1.00000\n \n −\n \n 1.00000i\n \n −1.00000\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(602\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(603\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(604\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(605\\)\n \n −1.36603\n \n +\n \n 0.366025i\n \n −1.36603\n \n +\n \n 0.366025i\n
\n \\(606\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(607\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.965926\n \n −\n \n 0.258819i\n \n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \n \\(0.0833333\\pi\\)\n
\n \\(608\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(609\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(610\\)\n \n\n \n −\n \n 2.00000i\n \n\n \n −\n \n 2.00000i\n
\n \\(611\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(612\\)\n \n −0.866025\n \n −\n \n 0.500000i\n \n −0.866025\n \n −\n \n 0.500000i\n
\n \\(613\\)\n \n −1.00000\n \n +\n \n 1.73205i\n \n −1.00000\n \n +\n \n 1.73205i\n \n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(614\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(615\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(616\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(617\\)\n \n −1.00000\n \n +\n \n 1.00000i\n \n −1.00000\n \n +\n \n 1.00000i\n \n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(618\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(619\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.965926\n \n −\n \n 0.258819i\n \n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \n \\(0.916667\\pi\\)\n
\n \\(620\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(621\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(622\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(623\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(624\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(625\\)\n \n −0.500000\n \n −\n \n 0.866025i\n \n −0.500000\n \n −\n \n 0.866025i\n
\n \\(626\\)\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.366025\n \n −\n \n 1.36603i\n
\n \\(627\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(628\\)\n \n −1.00000\n \n −\n \n 1.73205i\n \n −1.00000\n \n −\n \n 1.73205i\n
\n \\(629\\)\n \n −1.00000\n \n +\n \n 1.00000i\n \n −1.00000\n \n +\n \n 1.00000i\n
\n \\(630\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(631\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(632\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(633\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(634\\)\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.366025\n \n +\n \n 1.36603i\n
\n \\(635\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(636\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(637\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(638\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(639\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(640\\)\n \n −1.36603\n \n +\n \n 0.366025i\n \n −1.36603\n \n +\n \n 0.366025i\n
\n \\(641\\)\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n \\(642\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(643\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.707107\n \n −\n \n 0.707107i\n \n \\(-0.250000\\pi\\)\n
\n −0.707107\n \n +\n \n 0.707107i\n \n \\(0.750000\\pi\\)\n
\n \\(644\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(645\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(646\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(647\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(648\\)\n \n 0.866025\n \n +\n \n 0.500000i\n \n 0.866025\n \n +\n \n 0.500000i\n
\n \\(649\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(650\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(651\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(652\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(653\\)\n \n 0.366025\n \n −\n \n 1.36603i\n \n 0.366025\n \n −\n \n 1.36603i\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n \\(654\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(655\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(656\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n
\n \\(657\\)\n \n 1.00000\n \n +\n \n 1.00000i\n \n 1.00000\n \n +\n \n 1.00000i\n
\n \\(658\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(659\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(660\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(661\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(662\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(663\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(664\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(665\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(666\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n
\n \\(667\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(668\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(669\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(670\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(671\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(672\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(673\\)\n \n −1.00000\n \n −\n \n 1.00000i\n \n −1.00000\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(674\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n
\n \\(675\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(676\\)\n \n −0.500000\n \n +\n \n 0.866025i\n \n −0.500000\n \n +\n \n 0.866025i\n
\n \\(677\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(678\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(679\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(680\\)\n \n 1.00000\n \n +\n \n 1.00000i\n \n 1.00000\n \n +\n \n 1.00000i\n
\n \\(681\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(682\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(683\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.258819\n \n −\n \n 0.965926i\n \n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \n \\(0.416667\\pi\\)\n
\n \\(684\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(685\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(686\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(687\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(688\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(689\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(690\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(691\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.258819\n \n −\n \n 0.965926i\n \n \\(-0.416667\\pi\\)\n
\n −0.258819\n \n +\n \n 0.965926i\n \n \\(0.583333\\pi\\)\n
\n \\(692\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n
\n \\(693\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(694\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(695\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(696\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(697\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n
\n \\(698\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(699\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(700\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(701\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(702\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(703\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(704\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(705\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(706\\)\n \n\n \n −\n \n 2.00000i\n \n\n \n −\n \n 2.00000i\n
\n \\(707\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(708\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(709\\)\n \n −1.36603\n \n −\n \n 0.366025i\n \n −1.36603\n \n −\n \n 0.366025i\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(710\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(711\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(712\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(713\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(714\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(715\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(716\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(717\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(718\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(719\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.965926\n \n −\n \n 0.258819i\n \n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \n \\(0.0833333\\pi\\)\n
\n \\(720\\)\n \n −1.00000\n \n −\n \n 1.00000i\n \n −1.00000\n \n −\n \n 1.00000i\n
\n \\(721\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(722\\)\n \n\n \n\n \n 1.00000i\n \n\n \n\n \n 1.00000i\n
\n \\(723\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(724\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n
\n \\(725\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n
\n \\(726\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(727\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(728\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(729\\)\n \n\n \n\n \n 1.00000i\n \n\n \n\n \n 1.00000i\n
\n \\(730\\)\n \n −1.00000\n \n −\n \n 1.73205i\n \n −1.00000\n \n −\n \n 1.73205i\n
\n \\(731\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(732\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(733\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(734\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(735\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(736\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(737\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(738\\)\n \n −1.36603\n \n +\n \n 0.366025i\n \n −1.36603\n \n +\n \n 0.366025i\n
\n \\(739\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(740\\)\n \n −1.73205\n \n +\n \n 1.00000i\n \n −1.73205\n \n +\n \n 1.00000i\n
\n \\(741\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(742\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(743\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.707107\n \n −\n \n 0.707107i\n \n \\(-0.250000\\pi\\)\n
\n −0.707107\n \n +\n \n 0.707107i\n \n \\(0.750000\\pi\\)\n
\n \\(744\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(745\\)\n \n 0.732051\n \n +\n \n 2.73205i\n \n 0.732051\n \n +\n \n 2.73205i\n
\n \\(746\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(747\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(748\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(749\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(750\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(751\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.965926\n \n −\n \n 0.258819i\n \n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \n \\(0.0833333\\pi\\)\n
\n \\(752\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(753\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(754\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(755\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(756\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(757\\)\n \n\n \n\n \n 2.00000i\n \n\n \n\n \n 2.00000i\n \n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(758\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(759\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(760\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(761\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(762\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(763\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(764\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(765\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n
\n \\(766\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(767\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(768\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(769\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(770\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(771\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(772\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n
\n \\(773\\)\n \n −1.73205\n \n −\n \n 1.00000i\n \n −1.73205\n \n −\n \n 1.00000i\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n \\(774\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(775\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(776\\)\n \n 1.00000\n \n +\n \n 1.00000i\n \n 1.00000\n \n +\n \n 1.00000i\n
\n \\(777\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(778\\)\n \n 2.00000\n \n\n \n\n \n 2.00000\n \n\n \n\n
\n \\(779\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(780\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(781\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(782\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(783\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(784\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(785\\)\n \n −2.00000\n \n +\n \n 2.00000i\n \n −2.00000\n \n +\n \n 2.00000i\n
\n \\(786\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(787\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.258819\n \n −\n \n 0.965926i\n \n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \n \\(0.416667\\pi\\)\n
\n \\(788\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n
\n \\(789\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(790\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(791\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(792\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(793\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(794\\)\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.366025\n \n +\n \n 1.36603i\n
\n \\(795\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(796\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(797\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(798\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(799\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(800\\)\n \n 0.500000\n \n +\n \n 0.866025i\n \n 0.500000\n \n +\n \n 0.866025i\n
\n \\(801\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(802\\)\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.366025\n \n +\n \n 1.36603i\n
\n \\(803\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(804\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(805\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(806\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(807\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(808\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(809\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(810\\)\n \n 0.366025\n \n −\n \n 1.36603i\n \n 0.366025\n \n −\n \n 1.36603i\n
\n \\(811\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.707107\n \n −\n \n 0.707107i\n \n \\(-0.250000\\pi\\)\n
\n −0.707107\n \n +\n \n 0.707107i\n \n \\(0.750000\\pi\\)\n
\n \\(812\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(813\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(814\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(815\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(816\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(817\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(818\\)\n \n\n \n −\n \n 2.00000i\n \n\n \n −\n \n 2.00000i\n
\n \\(819\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(820\\)\n \n 2.00000\n \n\n \n\n \n 2.00000\n \n\n \n\n
\n \\(821\\)\n \n −1.36603\n \n −\n \n 0.366025i\n \n −1.36603\n \n −\n \n 0.366025i\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(822\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(823\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.965926\n \n −\n \n 0.258819i\n \n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \n \\(0.916667\\pi\\)\n
\n \\(824\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(825\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(826\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(827\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.707107\n \n −\n \n 0.707107i\n \n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \n \\(0.250000\\pi\\)\n
\n \\(828\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(829\\)\n \n 1.00000\n \n −\n \n 1.73205i\n \n 1.00000\n \n −\n \n 1.73205i\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n \\(830\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(831\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(832\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(833\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(834\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(835\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(836\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(837\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(838\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(839\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.707107\n \n −\n \n 0.707107i\n \n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \n \\(0.250000\\pi\\)\n
\n \\(840\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(841\\)\n \n\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n
\n \\(842\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(843\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(844\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(845\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n
\n \\(846\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(847\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(848\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(849\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(850\\)\n \n 0.500000\n \n −\n \n 0.866025i\n \n 0.500000\n \n −\n \n 0.866025i\n
\n \\(851\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(852\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(853\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n \\(854\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(855\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(856\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(857\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(858\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(859\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(860\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(861\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(862\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(863\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(864\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(865\\)\n \n −1.73205\n \n −\n \n 1.00000i\n \n −1.73205\n \n −\n \n 1.00000i\n
\n \\(866\\)\n \n −1.00000\n \n −\n \n 1.73205i\n \n −1.00000\n \n −\n \n 1.73205i\n
\n \\(867\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(868\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(869\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(870\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(871\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(872\\)\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.366025\n \n +\n \n 1.36603i\n
\n \\(873\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n
\n \\(874\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(875\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(876\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(877\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n \n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(878\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(879\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(880\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(881\\)\n \n −1.00000\n \n +\n \n 1.00000i\n \n −1.00000\n \n +\n \n 1.00000i\n \n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(882\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(883\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(884\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(885\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(886\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(887\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.965926\n \n −\n \n 0.258819i\n \n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \n \\(0.0833333\\pi\\)\n
\n \\(888\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(889\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(890\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(891\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(892\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(893\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(894\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(895\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(896\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(897\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(898\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n
\n \\(899\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(900\\)\n \n −0.500000\n \n +\n \n 0.866025i\n \n −0.500000\n \n +\n \n 0.866025i\n
\n \\(901\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(902\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(903\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(904\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n
\n \\(905\\)\n \n −1.00000\n \n −\n \n 1.73205i\n \n −1.00000\n \n −\n \n 1.73205i\n
\n \\(906\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(907\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.965926\n \n −\n \n 0.258819i\n \n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \n \\(0.916667\\pi\\)\n
\n \\(908\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(909\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(910\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(911\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.707107\n \n −\n \n 0.707107i\n \n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \n \\(0.250000\\pi\\)\n
\n \\(912\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(913\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(914\\)\n \n 1.00000\n \n −\n \n 1.73205i\n \n 1.00000\n \n −\n \n 1.73205i\n
\n \\(915\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(916\\)\n \n\n \n\n \n 2.00000i\n \n\n \n\n \n 2.00000i\n
\n \\(917\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(918\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(919\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(920\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(921\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(922\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(923\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(924\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(925\\)\n \n 1.00000\n \n +\n \n 1.00000i\n \n 1.00000\n \n +\n \n 1.00000i\n
\n \\(926\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(927\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(928\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n
\n \\(929\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n \n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(930\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(931\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(932\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n
\n \\(933\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(934\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(935\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(936\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(937\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(938\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(939\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(940\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(941\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(942\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(943\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(944\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(945\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(946\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(947\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.965926\n \n −\n \n 0.258819i\n \n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \n \\(0.0833333\\pi\\)\n
\n \\(948\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(949\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(950\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(951\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(952\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(953\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(954\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(955\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(956\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(957\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(958\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(959\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(960\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(961\\)\n \n −0.866025\n \n +\n \n 0.500000i\n \n −0.866025\n \n +\n \n 0.500000i\n
\n \\(962\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(963\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(964\\)\n \n −1.36603\n \n −\n \n 0.366025i\n \n −1.36603\n \n −\n \n 0.366025i\n
\n \\(965\\)\n \n 2.00000\n \n\n \n\n \n 2.00000\n \n\n \n\n
\n \\(966\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(967\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(968\\)\n \n 0.500000\n \n +\n \n 0.866025i\n \n 0.500000\n \n +\n \n 0.866025i\n
\n \\(969\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(970\\)\n \n 1.00000\n \n −\n \n 1.73205i\n \n 1.00000\n \n −\n \n 1.73205i\n
\n \\(971\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(972\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(973\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(974\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(975\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(976\\)\n \n −1.36603\n \n +\n \n 0.366025i\n \n −1.36603\n \n +\n \n 0.366025i\n
\n \\(977\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(978\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(979\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(980\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(981\\)\n \n −1.00000\n \n +\n \n 1.00000i\n \n −1.00000\n \n +\n \n 1.00000i\n
\n \\(982\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(983\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.258819\n \n −\n \n 0.965926i\n \n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \n \\(0.416667\\pi\\)\n
\n \\(984\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(985\\)\n \n −1.00000\n \n −\n \n 1.73205i\n \n −1.00000\n \n −\n \n 1.73205i\n
\n \\(986\\)\n \n −1.00000\n \n −\n \n 1.00000i\n \n −1.00000\n \n −\n \n 1.00000i\n
\n \\(987\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(988\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(989\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(990\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(991\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.258819\n \n −\n \n 0.965926i\n \n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \n \\(0.416667\\pi\\)\n
\n \\(992\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(993\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(994\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(995\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(996\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(997\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(998\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(999\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n
\n
\n \n Display \\(a_p\\) with \\(p\\) up to:\n 50\n 250\n 1000\n \n\n \n (See \\(a_n\\) instead)\n \n\n \n (See \\(a_n\\) instead)\n \n\n \n (See \\(a_n\\) instead)\n \n \n Display \\(a_n\\) with \\(n\\) up to:\n 50\n 250\n 1000\n \n\n \n (See only \\(a_p\\))\n \n\n \n (See only \\(a_p\\))\n \n\n \n (See only \\(a_p\\))\n \n
\n\n\n

Twists

\n\n\n\n\n \n \n \n \n \n \n \n\n\n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n
       By twisting character
CharParityOrdTypeTwistMinDim
1.1even1trivial3332.1.bc.b.2027.14
4.3odd2CM3332.1.bc.b.2027.14
7.2even3inner3332.1.bc.b.667.14
7.3odd668.1.f.a.55.1yes2
7.4even33332.1.m.b.2843.12
7.5odd63332.1.bc.c.667.14
7.6odd23332.1.bc.c.2027.14
17.13even4inner3332.1.bc.b.2223.14
21.17even6612.1.l.a.55.12
28.3even668.1.f.a.55.1yes2
28.11odd63332.1.m.b.2843.12
28.19even63332.1.bc.c.667.14
28.23odd6inner3332.1.bc.b.667.14
28.27even23332.1.bc.c.2027.14
35.3even121700.1.n.a.599.12
35.17even121700.1.n.b.599.12
35.24odd61700.1.p.a.1551.12
56.3even61088.1.p.a.191.12
56.45odd61088.1.p.a.191.12
68.47odd4inner3332.1.bc.b.2223.14
84.59odd6612.1.l.a.55.12
119.3even481156.1.g.b.155.18
119.10even481156.1.g.b.179.18
119.13odd43332.1.bc.c.2223.14
119.24even481156.1.g.b.179.28
119.30even12inner3332.1.bc.b.863.14
119.31even481156.1.g.b.155.28
119.38odd121156.1.f.b.251.12
119.45even481156.1.g.b.399.18
119.47odd123332.1.bc.c.863.14
119.59odd241156.1.c.b.579.12
119.66odd241156.1.d.a.1155.22
119.73even481156.1.g.b.423.28
119.80even481156.1.g.b.423.18
119.81even123332.1.m.b.3039.12
119.87odd241156.1.d.a.1155.12
119.94odd241156.1.c.b.579.22
119.101odd61156.1.f.b.327.12
119.108even481156.1.g.b.399.28
119.115odd1268.1.f.a.47.12
140.3odd121700.1.n.a.599.12
140.59even61700.1.p.a.1551.12
140.87odd121700.1.n.b.599.12
357.353even12612.1.l.a.523.12
476.3odd481156.1.g.b.155.18
476.31odd481156.1.g.b.155.28
476.47even123332.1.bc.c.863.14
476.59even241156.1.c.b.579.12
476.87even241156.1.d.a.1155.12
476.115even1268.1.f.a.47.12
476.143odd481156.1.g.b.179.28
476.199odd481156.1.g.b.423.18
476.227odd481156.1.g.b.399.28
476.251even43332.1.bc.c.2223.14
476.283odd481156.1.g.b.399.18
476.311odd481156.1.g.b.423.28
476.319odd123332.1.m.b.3039.12
476.339even61156.1.f.b.327.12
476.367odd481156.1.g.b.179.18
476.387odd12inner3332.1.bc.b.863.14
476.395even121156.1.f.b.251.12
476.423even241156.1.d.a.1155.22
476.451even241156.1.c.b.579.22
595.234odd121700.1.p.a.251.12
595.353even121700.1.n.b.999.12
595.472even121700.1.n.a.999.12
952.115even121088.1.p.a.319.12
952.829odd121088.1.p.a.319.12
1428.1067odd12612.1.l.a.523.12
2380.1067odd121700.1.n.a.999.12
2380.1543odd121700.1.n.b.999.12
2380.2019even121700.1.p.a.251.12
\n
    
\n\n\n\n\n \n \n \n \n \n \n \n\n\n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n
        By twisted newform
TwistMinDimCharParityOrdType
68.1.f.a.47.12119.115odd12
68.1.f.a.47.12476.115even12
68.1.f.a.55.1yes27.3odd6
68.1.f.a.55.1yes228.3even6
612.1.l.a.55.1221.17even6
612.1.l.a.55.1284.59odd6
612.1.l.a.523.12357.353even12
612.1.l.a.523.121428.1067odd12
1088.1.p.a.191.1256.3even6
1088.1.p.a.191.1256.45odd6
1088.1.p.a.319.12952.115even12
1088.1.p.a.319.12952.829odd12
1156.1.c.b.579.12119.59odd24
1156.1.c.b.579.12476.59even24
1156.1.c.b.579.22119.94odd24
1156.1.c.b.579.22476.451even24
1156.1.d.a.1155.12119.87odd24
1156.1.d.a.1155.12476.87even24
1156.1.d.a.1155.22119.66odd24
1156.1.d.a.1155.22476.423even24
1156.1.f.b.251.12119.38odd12
1156.1.f.b.251.12476.395even12
1156.1.f.b.327.12119.101odd6
1156.1.f.b.327.12476.339even6
1156.1.g.b.155.18119.3even48
1156.1.g.b.155.18476.3odd48
1156.1.g.b.155.28119.31even48
1156.1.g.b.155.28476.31odd48
1156.1.g.b.179.18119.10even48
1156.1.g.b.179.18476.367odd48
1156.1.g.b.179.28119.24even48
1156.1.g.b.179.28476.143odd48
1156.1.g.b.399.18119.45even48
1156.1.g.b.399.18476.283odd48
1156.1.g.b.399.28119.108even48
1156.1.g.b.399.28476.227odd48
1156.1.g.b.423.18119.80even48
1156.1.g.b.423.18476.199odd48
1156.1.g.b.423.28119.73even48
1156.1.g.b.423.28476.311odd48
1700.1.n.a.599.1235.3even12
1700.1.n.a.599.12140.3odd12
1700.1.n.a.999.12595.472even12
1700.1.n.a.999.122380.1067odd12
1700.1.n.b.599.1235.17even12
1700.1.n.b.599.12140.87odd12
1700.1.n.b.999.12595.353even12
1700.1.n.b.999.122380.1543odd12
1700.1.p.a.251.12595.234odd12
1700.1.p.a.251.122380.2019even12
1700.1.p.a.1551.1235.24odd6
1700.1.p.a.1551.12140.59even6
3332.1.m.b.2843.127.4even3
3332.1.m.b.2843.1228.11odd6
3332.1.m.b.3039.12119.81even12
3332.1.m.b.3039.12476.319odd12
3332.1.bc.b.667.147.2even3inner
3332.1.bc.b.667.1428.23odd6inner
3332.1.bc.b.863.14119.30even12inner
3332.1.bc.b.863.14476.387odd12inner
3332.1.bc.b.2027.141.1even1trivial
3332.1.bc.b.2027.144.3odd2CM
3332.1.bc.b.2223.1417.13even4inner
3332.1.bc.b.2223.1468.47odd4inner
3332.1.bc.c.667.147.5odd6
3332.1.bc.c.667.1428.19even6
3332.1.bc.c.863.14119.47odd12
3332.1.bc.c.863.14476.47even12
3332.1.bc.c.2027.147.6odd2
3332.1.bc.c.2027.1428.27even2
3332.1.bc.c.2223.14119.13odd4
3332.1.bc.c.2223.14476.251even4
\n
\n\n\n\n

\n
\n
\n\n\n
\n\n

This project is supported by grants from the US National Science Foundation, the UK Engineering and Physical Sciences Research Council, and the Simons Foundation.

\n
\n Contact\n ·\n Citation\n ·\n Acknowledgments\n ·\n Editorial Board\n ·\n Source\n ·\n SageMath version 10.1\n ·\n LMFDB Release 1.2.1\n
\n
\n\n"} +{"url": "https://www.lmfdb.org/ModularForm/GL2/Q/holomorphic/3332/1/bc/b/2027/1/", "content": "Show commands: Magma/ PariGP/ SageMath\n\n```\n[N,k,chi] = [3332,1,Mod(667,3332)]\n\nmf = mfinit([N,k,chi],0)\n\nlf = mfeigenbasis(mf)\n```\n\n```\nfrom sage.modular.dirichlet import DirichletCharacter\n\nH = DirichletGroup(3332, base_ring=CyclotomicField(12))\n\nchi = DirichletCharacter(H, H._module([6, 4, 9]))\n\nN = Newforms(chi, 1, names=\"a\")\n```\n\n```\n//Please install CHIMP (https://github.com/edgarcosta/CHIMP) if you want to run this code\n\nchi := DirichletCharacter(\"3332.667\");\n\nS:= CuspForms(chi, 1);\n\nN := Newforms(S);\n```\n\n| Level : | $N$ | $=$ | $3332 = 2^{2} \\cdot 7^{2} \\cdot 17$ |\n|---|---|---|---|\n| Weight : | $k$ | $=$ | $1$ |\n| Character orbit : | $[\\chi]$ | $=$ | 3332.bc (oforder12, degree4, not minimal ) |\n\n## Newform invariants\n\n```\nsage: f = N[0] # Warning: the index may be different\n```\n\n```\ngp: f = lf[1] \\\\ Warning: the index may be different\n```\n\n
Self dual :no
Analytic conductor :$1.66288462209$
Analytic rank :$0$
Dimension :$4$
Coefficient field :$\\Q(\\zeta_{12})$
\n\n```\ngp: f.mod \\\\ as an extension of the character field\n```\n\n
Defining polynomial :$x^{4} - x^{2} + 1$
Coefficient ring :$\\Z[a_1, a_2]$
Coefficient ring index :$1$
Twist minimal :no (minimal twist has level 68)
Projective image :$D_{4}$
Projective field :Galois closure of 4.2.19652.1
Artin image :$C_4\\wr C_2\\times C_6$
Artin field :Galois closure of $\\mathbb{Q}[x]/(x^{48} - \\cdots)$
\n\n## Embedding invariants\n\n| Embedding label | | | 2027.1 |\n|---|---|---|---|\n| Root | | | $0.866025 - 0.500000i$ of defining polynomial |\n| Character | $\\chi$ | $=$ | 3332.2027 |\n| Dual form | | | 3332.1.bc.b.863.1 |\n\n```\nsage: f.q_expansion() # note that sage often uses an isomorphic number field\n```\n\n```\ngp: mfcoefs(f, 20)\n```\n\n| $f(q)$ | $=$ | $q+(-0.866025 + 0.500000i) q^{2} +(0.500000 - 0.866025i) q^{4} +(-1.36603 - 0.366025i) q^{5} +1.00000i q^{8} +(-0.866025 + 0.500000i) q^{9} +(1.36603 - 0.366025i) q^{10} +(-0.500000 - 0.866025i) q^{16} +(-0.500000 + 0.866025i) q^{17} +(0.500000 - 0.866025i) q^{18} +(-1.00000 + 1.00000i) q^{20} +(0.866025 + 0.500000i) q^{25} +(1.00000 - 1.00000i) q^{29} +(0.866025 + 0.500000i) q^{32} -1.00000i q^{34} +1.00000i q^{36} +(1.36603 + 0.366025i) q^{37} +(0.366025 - 1.36603i) q^{40} +(-1.00000 - 1.00000i) q^{41} +(1.36603 - 0.366025i) q^{45} -1.00000 q^{50} +(-0.366025 + 1.36603i) q^{58} +(0.366025 - 1.36603i) q^{61} -1.00000 q^{64} +(0.500000 + 0.866025i) q^{68} +(-0.500000 - 0.866025i) q^{72} +(-0.366025 - 1.36603i) q^{73} +(-1.36603 + 0.366025i) q^{74} +(0.366025 + 1.36603i) q^{80} +(0.500000 - 0.866025i) q^{81} +(1.36603 + 0.366025i) q^{82} +(1.00000 - 1.00000i) q^{85} +(-1.00000 + 1.00000i) q^{90} +(1.00000 - 1.00000i) q^{97} +O(q^{100})$ |\n|---|---|---|\n| $\\operatorname{Tr}(f)(q)$ | $=$ | $4 q + 2 q^{4} - 2 q^{5} + 2 q^{10} - 2 q^{16} - 2 q^{17} + 2 q^{18} - 4 q^{20} + 4 q^{29} + 2 q^{37} - 2 q^{40} - 4 q^{41} + 2 q^{45} - 4 q^{50} + 2 q^{58} - 2 q^{61} - 4 q^{64} + 2 q^{68} - 2 q^{72} + 2 q^{73}+ \\cdots + 4 q^{97}+O(q^{100})$ |\n\n## Character values\n\nWe give the values of $\\chi$ on generators for $\\left(\\mathbb{Z}/3332\\mathbb{Z}\\right)^\\times$ .\n\n| $n$ | $785$ | $885$ | $1667$ |\n|---|---|---|---|\n| $\\chi(n)$ | $e\\left(\\frac{3}{4}\\right)$ | $e\\left(\\frac{2}{3}\\right)$ | $-1$ |\n\n## Coefficient data\n\nFor each $n$ we display the coefficients of the $q$ -expansion $a_n$ , the Satake parameters $\\alpha_p$ , and the Satake angles $\\theta_p = \\textrm{Arg}(\\alpha_p)$ .\n\n(See $a_n$ instead)(See $a_n$ instead)(See $a_n$ instead)(See only $a_p$ )(See only $a_p$ )(See only $a_p$ )\n\n
$n$$a_n$$a_n / n^{(k-1)/2}$$\\alpha_n$$\\theta_n$
$p$$a_p$$a_p / p^{(k-1)/2}$$\\alpha_p$$\\theta_p$
$2$−0.866025+0.500000i−0.866025+0.500000i
$3$00−0.2588190.965926i$-0.583333\\pi$
0.258819+0.965926i$0.416667\\pi$
$4$0.5000000.866025i0.5000000.866025i
$5$−1.366030.366025i−1.366030.366025i−0.5000000.866025i$-0.666667\\pi$
−0.866025+0.500000i$0.833333\\pi$
$6$00
$7$00
$8$1.00000i1.00000i
$9$−0.866025+0.500000i−0.866025+0.500000i
$10$1.366030.366025i1.366030.366025i
$11$000.9659260.258819i$-0.0833333\\pi$
−0.965926+0.258819i$0.916667\\pi$
$12$00
$13$001.00000i$-0.5\\pi$
1.00000i$0.5\\pi$
$14$00
$15$00
$16$−0.5000000.866025i−0.5000000.866025i
$17$−0.500000+0.866025i−0.500000+0.866025i
$18$0.5000000.866025i0.5000000.866025i
$19$000.8660250.500000i$-0.166667\\pi$
−0.866025+0.500000i$0.833333\\pi$
$20$−1.00000+1.00000i−1.00000+1.00000i
$21$00
$22$00
$23$000.2588190.965926i$-0.416667\\pi$
−0.258819+0.965926i$0.583333\\pi$
$24$00
$25$0.866025+0.500000i0.866025+0.500000i
$26$00
$27$00
$28$00
$29$1.000001.00000i1.000001.00000i1.00000i$-0.5\\pi$
1.00000$0$
$30$00
$31$00−0.2588190.965926i$-0.583333\\pi$
0.258819+0.965926i$0.416667\\pi$
$32$0.866025+0.500000i0.866025+0.500000i
$33$00
$34$1.00000i1.00000i
$35$00
$36$1.00000i1.00000i
$37$1.36603+0.366025i1.36603+0.366025i0.8660250.500000i$-0.166667\\pi$
0.500000+0.866025i$0.333333\\pi$
$38$00
$39$00
$40$0.3660251.36603i0.3660251.36603i
$41$−1.000001.00000i−1.000001.00000i1.00000i$-0.5\\pi$
−1.00000$\\pi$
$42$00
$43$001.00000i$-0.5\\pi$
1.00000i$0.5\\pi$
$44$00
$45$1.366030.366025i1.366030.366025i
$46$00
$47$00−0.5000000.866025i$-0.666667\\pi$
0.500000+0.866025i$0.333333\\pi$
$48$00
$49$00
$50$−1.00000−1.00000
$51$00
$52$00
$53$000.5000000.866025i$-0.333333\\pi$
−0.500000+0.866025i$0.666667\\pi$
$54$00
$55$00
$56$00
$57$00
$58$−0.366025+1.36603i−0.366025+1.36603i
$59$00−0.8660250.500000i$-0.833333\\pi$
0.866025+0.500000i$0.166667\\pi$
$60$00
$61$0.3660251.36603i0.3660251.36603i−0.5000000.866025i$-0.666667\\pi$
0.8660250.500000i$-0.166667\\pi$
$62$00
$63$00
$64$−1.00000−1.00000
$65$00
$66$00
$67$000.5000000.866025i$-0.333333\\pi$
−0.500000+0.866025i$0.666667\\pi$
$68$0.500000+0.866025i0.500000+0.866025i
$69$00
$70$00
$71$000.7071070.707107i$-0.250000\\pi$
−0.707107+0.707107i$0.750000\\pi$
$72$−0.5000000.866025i−0.5000000.866025i
$73$−0.3660251.36603i−0.3660251.36603i−0.8660250.500000i$-0.833333\\pi$
0.5000000.866025i$-0.333333\\pi$
$74$−1.36603+0.366025i−1.36603+0.366025i
$75$00
$76$00
$77$00
$78$00
$79$000.2588190.965926i$-0.416667\\pi$
−0.258819+0.965926i$0.583333\\pi$
$80$0.366025+1.36603i0.366025+1.36603i
$81$0.5000000.866025i0.5000000.866025i
$82$1.36603+0.366025i1.36603+0.366025i
$83$001.00000i$-0.5\\pi$
1.00000i$0.5\\pi$
$84$00
$85$1.000001.00000i1.000001.00000i
$86$00
$87$00
$88$00
$89$000.8660250.500000i$-0.166667\\pi$
−0.866025+0.500000i$0.833333\\pi$
$90$−1.00000+1.00000i−1.00000+1.00000i
$91$00
$92$00
$93$00
$94$00
$95$00
$96$00
$97$1.000001.00000i1.000001.00000i1.00000i$-0.5\\pi$
1.00000$0$
$98$00
$99$00
$100$0.8660250.500000i0.8660250.500000i
$101$00−0.8660250.500000i$-0.833333\\pi$
0.866025+0.500000i$0.166667\\pi$
$102$00
$103$00−0.5000000.866025i$-0.666667\\pi$
0.500000+0.866025i$0.333333\\pi$
$104$00
$105$00
$106$00
$107$00−0.9659260.258819i$-0.916667\\pi$
0.965926+0.258819i$0.0833333\\pi$
$108$00
$109$1.366030.366025i1.366030.366025i0.5000000.866025i$-0.333333\\pi$
0.866025+0.500000i$0.166667\\pi$
$110$00
$111$00
$112$00
$113$−1.000001.00000i−1.000001.00000i1.00000i$-0.5\\pi$
−1.00000$\\pi$
$114$00
$115$00
$116$−0.3660251.36603i−0.3660251.36603i
$117$00
$118$00
$119$00
$120$00
$121$0.8660250.500000i0.8660250.500000i
$122$0.366025+1.36603i0.366025+1.36603i
$123$00
$124$00
$125$00
$126$00
$127$001.00000i$-0.5\\pi$
1.00000i$0.5\\pi$
$128$0.8660250.500000i0.8660250.500000i
$129$00
$130$00
$131$00−0.9659260.258819i$-0.916667\\pi$
0.965926+0.258819i$0.0833333\\pi$
$132$00
$133$00
$134$00
$135$00
$136$−0.8660250.500000i−0.8660250.500000i
$137$00−0.8660250.500000i$-0.833333\\pi$
0.866025+0.500000i$0.166667\\pi$
$138$00
$139$000.7071070.707107i$-0.250000\\pi$
−0.707107+0.707107i$0.750000\\pi$
$140$00
$141$00
$142$00
$143$00
$144$0.866025+0.500000i0.866025+0.500000i
$145$−1.73205+1.00000i−1.73205+1.00000i
$146$1.00000+1.00000i1.00000+1.00000i
$147$00
$148$1.000001.00000i1.000001.00000i
$149$−1.000001.73205i−1.000001.73205i−0.5000000.866025i$-0.666667\\pi$
−0.5000000.866025i$-0.666667\\pi$
$150$00
$151$00−0.8660250.500000i$-0.833333\\pi$
0.866025+0.500000i$0.166667\\pi$
$152$00
$153$1.00000i1.00000i
$154$00
$155$00
$156$00
$157$1.000001.73205i1.000001.73205i0.5000000.866025i$-0.333333\\pi$
0.5000000.866025i$-0.333333\\pi$
$158$00
$159$00
$160$−1.000001.00000i−1.000001.00000i
$161$00
$162$1.00000i1.00000i
$163$000.2588190.965926i$-0.416667\\pi$
−0.258819+0.965926i$0.583333\\pi$
$164$−1.36603+0.366025i−1.36603+0.366025i
$165$00
$166$00
$167$000.7071070.707107i$-0.250000\\pi$
−0.707107+0.707107i$0.750000\\pi$
$168$00
$169$−1.00000−1.00000
$170$−0.366025+1.36603i−0.366025+1.36603i
$171$00
$172$00
$173$1.36603+0.366025i1.36603+0.366025i0.8660250.500000i$-0.166667\\pi$
0.500000+0.866025i$0.333333\\pi$
$174$00
$175$00
$176$00
$177$00
$178$00
$179$00−0.8660250.500000i$-0.833333\\pi$
0.866025+0.500000i$0.166667\\pi$
$180$0.3660251.36603i0.3660251.36603i
$181$1.00000+1.00000i1.00000+1.00000i1.00000$0$
1.00000i$0.5\\pi$
$182$00
$183$00
$184$00
$185$−1.732051.00000i−1.732051.00000i
$186$00
$187$00
$188$00
$189$00
$190$00
$191$00−0.5000000.866025i$-0.666667\\pi$
0.500000+0.866025i$0.333333\\pi$
$192$00
$193$−1.36603+0.366025i−1.36603+0.366025i−0.8660250.500000i$-0.833333\\pi$
−0.500000+0.866025i$0.666667\\pi$
$194$−0.366025+1.36603i−0.366025+1.36603i
$195$00
$196$00
$197$1.00000+1.00000i1.00000+1.00000i1.00000$0$
1.00000i$0.5\\pi$
$198$00
$199$00−0.2588190.965926i$-0.583333\\pi$
0.258819+0.965926i$0.416667\\pi$
$200$−0.500000+0.866025i−0.500000+0.866025i
$201$00
$202$00
$203$00
$204$00
$205$1.00000+1.73205i1.00000+1.73205i
$206$00
$207$00
$208$00
$209$00
$210$00
$211$00−0.7071070.707107i$-0.750000\\pi$
0.707107+0.707107i$0.250000\\pi$
$212$00
$213$00
$214$00
$215$00
$216$00
$217$00
$218$−1.00000+1.00000i−1.00000+1.00000i
$219$00
$220$00
$221$00
$222$00
$223$001.00000i$-0.5\\pi$
1.00000i$0.5\\pi$
$224$00
$225$−1.00000−1.00000
$226$1.36603+0.366025i1.36603+0.366025i
$227$000.9659260.258819i$-0.0833333\\pi$
−0.965926+0.258819i$0.916667\\pi$
$228$00
$229$−1.73205+1.00000i−1.73205+1.00000i−0.866025+0.500000i$0.833333\\pi$
−0.866025+0.500000i$0.833333\\pi$
$230$00
$231$00
$232$1.00000+1.00000i1.00000+1.00000i
$233$1.36603+0.366025i1.36603+0.366025i0.8660250.500000i$-0.166667\\pi$
0.500000+0.866025i$0.333333\\pi$
$234$00
$235$00
$236$00
$237$00
$238$00
$239$001.00000$0$
−1.00000$\\pi$
$240$00
$241$−0.3660251.36603i−0.3660251.36603i−0.8660250.500000i$-0.833333\\pi$
0.5000000.866025i$-0.333333\\pi$
$242$−0.500000+0.866025i−0.500000+0.866025i
$243$00
$244$−1.000001.00000i−1.000001.00000i
$245$00
$246$00
$247$00
$248$00
$249$00
$250$00
$251$001.00000$0$
−1.00000$\\pi$
$252$00
$253$00
$254$00
$255$00
$256$−0.500000+0.866025i−0.500000+0.866025i
$257$1.732051.00000i1.732051.00000i0.8660250.500000i$-0.166667\\pi$
0.8660250.500000i$-0.166667\\pi$
$258$00
$259$00
$260$00
$261$−0.366025+1.36603i−0.366025+1.36603i
$262$00
$263$00−0.8660250.500000i$-0.833333\\pi$
0.866025+0.500000i$0.166667\\pi$
$264$00
$265$00
$266$00
$267$00
$268$00
$269$0.366025+1.36603i0.366025+1.36603i0.866025+0.500000i$0.166667\\pi$
−0.500000+0.866025i$0.666667\\pi$
$270$00
$271$00−0.5000000.866025i$-0.666667\\pi$
0.500000+0.866025i$0.333333\\pi$
$272$1.000001.00000
$273$00
$274$00
$275$00
$276$00
$277$0.366025+1.36603i0.366025+1.36603i0.866025+0.500000i$0.166667\\pi$
−0.500000+0.866025i$0.666667\\pi$
$278$00
$279$00
$280$00
$281$001.00000$0$
−1.00000$\\pi$
$282$00
$283$000.9659260.258819i$-0.0833333\\pi$
−0.965926+0.258819i$0.916667\\pi$
$284$00
$285$00
$286$00
$287$00
$288$−1.00000−1.00000
$289$−0.5000000.866025i−0.5000000.866025i
$290$1.000001.73205i1.000001.73205i
$291$00
$292$−1.366030.366025i−1.366030.366025i
$293$2.000002.000001.00000$0$
1.00000$0$
$294$00
$295$00
$296$−0.366025+1.36603i−0.366025+1.36603i
$297$00
$298$1.73205+1.00000i1.73205+1.00000i
$299$00
$300$00
$301$00
$302$00
$303$00
$304$00
$305$−1.00000+1.73205i−1.00000+1.73205i
$306$0.500000+0.866025i0.500000+0.866025i
$307$001.00000$0$
−1.00000$\\pi$
$308$00
$309$00
$310$00
$311$00−0.2588190.965926i$-0.583333\\pi$
0.258819+0.965926i$0.416667\\pi$
$312$00
$313$−0.366025+1.36603i−0.366025+1.36603i0.500000+0.866025i$0.333333\\pi$
−0.866025+0.500000i$0.833333\\pi$
$314$2.00000i2.00000i
$315$00
$316$00
$317$0.3660251.36603i0.3660251.36603i−0.5000000.866025i$-0.666667\\pi$
0.8660250.500000i$-0.166667\\pi$
$318$00
$319$00
$320$1.36603+0.366025i1.36603+0.366025i
$321$00
$322$00
$323$00
$324$−0.5000000.866025i−0.5000000.866025i
$325$00
$326$00
$327$00
$328$1.000001.00000i1.000001.00000i
$329$00
$330$00
$331$000.8660250.500000i$-0.166667\\pi$
−0.866025+0.500000i$0.833333\\pi$
$332$00
$333$−1.36603+0.366025i−1.36603+0.366025i
$334$00
$335$00
$336$00
$337$1.000001.00000i1.000001.00000i1.00000i$-0.5\\pi$
1.00000$0$
$338$0.8660250.500000i0.8660250.500000i
$339$00
$340$−0.3660251.36603i−0.3660251.36603i
$341$00
$342$00
$343$00
$344$00
$345$00
$346$−1.36603+0.366025i−1.36603+0.366025i
$347$000.9659260.258819i$-0.0833333\\pi$
−0.965926+0.258819i$0.916667\\pi$
$348$00
$349$001.00000$0$
−1.00000$\\pi$
$350$00
$351$00
$352$00
$353$−1.00000+1.73205i−1.00000+1.73205i−0.500000+0.866025i$0.666667\\pi$
−0.500000+0.866025i$0.666667\\pi$
$354$00
$355$00
$356$00
$357$00
$358$00
$359$000.8660250.500000i$-0.166667\\pi$
−0.866025+0.500000i$0.833333\\pi$
$360$0.366025+1.36603i0.366025+1.36603i
$361$0.5000000.866025i0.5000000.866025i
$362$−1.366030.366025i−1.366030.366025i
$363$00
$364$00
$365$2.00000i2.00000i
$366$00
$367$000.9659260.258819i$-0.0833333\\pi$
−0.965926+0.258819i$0.916667\\pi$
$368$00
$369$1.36603+0.366025i1.36603+0.366025i
$370$2.000002.00000
$371$00
$372$00
$373$000.8660250.500000i$-0.166667\\pi$
−0.866025+0.500000i$0.833333\\pi$
$374$00
$375$00
$376$00
$377$00
$378$00
$379$000.7071070.707107i$-0.250000\\pi$
−0.707107+0.707107i$0.750000\\pi$
$380$00
$381$00
$382$00
$383$000.8660250.500000i$-0.166667\\pi$
−0.866025+0.500000i$0.833333\\pi$
$384$00
$385$00
$386$1.000001.00000i1.000001.00000i
$387$00
$388$−0.3660251.36603i−0.3660251.36603i
$389$−1.732051.00000i−1.732051.00000i−0.8660250.500000i$-0.833333\\pi$
−0.8660250.500000i$-0.833333\\pi$
$390$00
$391$00
$392$00
$393$00
$394$−1.366030.366025i−1.366030.366025i
$395$00
$396$00
$397$0.3660251.36603i0.3660251.36603i−0.5000000.866025i$-0.666667\\pi$
0.8660250.500000i$-0.166667\\pi$
$398$00
$399$00
$400$1.00000i1.00000i
$401$0.3660251.36603i0.3660251.36603i−0.5000000.866025i$-0.666667\\pi$
0.8660250.500000i$-0.166667\\pi$
$402$00
$403$00
$404$00
$405$−1.00000+1.00000i−1.00000+1.00000i
$406$00
$407$00
$408$00
$409$−1.00000+1.73205i−1.00000+1.73205i−0.500000+0.866025i$0.666667\\pi$
−0.500000+0.866025i$0.666667\\pi$
$410$−1.732051.00000i−1.732051.00000i
$411$00
$412$00
$413$00
$414$00
$415$00
$416$00
$417$00
$418$00
$419$00−0.7071070.707107i$-0.750000\\pi$
0.707107+0.707107i$0.250000\\pi$
$420$00
$421$001.00000i$-0.5\\pi$
1.00000i$0.5\\pi$
$422$00
$423$00
$424$00
$425$−0.866025+0.500000i−0.866025+0.500000i
$426$00
$427$00
$428$00
$429$00
$430$00
$431$000.9659260.258819i$-0.0833333\\pi$
−0.965926+0.258819i$0.916667\\pi$
$432$00
$433$2.00000i2.00000i1.00000i$0.5\\pi$
1.00000i$0.5\\pi$
$434$00
$435$00
$436$0.3660251.36603i0.3660251.36603i
$437$00
$438$00
$439$00−0.9659260.258819i$-0.916667\\pi$
0.965926+0.258819i$0.0833333\\pi$
$440$00
$441$00
$442$00
$443$00−0.5000000.866025i$-0.666667\\pi$
0.500000+0.866025i$0.333333\\pi$
$444$00
$445$00
$446$00
$447$00
$448$00
$449$−1.000001.00000i−1.000001.00000i1.00000i$-0.5\\pi$
−1.00000$\\pi$
$450$0.8660250.500000i0.8660250.500000i
$451$00
$452$−1.36603+0.366025i−1.36603+0.366025i
$453$00
$454$00
$455$00
$456$00
$457$−1.73205+1.00000i−1.73205+1.00000i−0.866025+0.500000i$0.833333\\pi$
−0.866025+0.500000i$0.833333\\pi$
$458$1.000001.73205i1.000001.73205i
$459$00
$460$00
$461$001.00000$0$
−1.00000$\\pi$
$462$00
$463$001.00000$0$
−1.00000$\\pi$
$464$−1.366030.366025i−1.366030.366025i
$465$00
$466$−1.36603+0.366025i−1.36603+0.366025i
$467$000.8660250.500000i$-0.166667\\pi$
−0.866025+0.500000i$0.833333\\pi$
$468$00
$469$00
$470$00
$471$00
$472$00
$473$00
$474$00
$475$00
$476$00
$477$00
$478$00
$479$00−0.2588190.965926i$-0.583333\\pi$
0.258819+0.965926i$0.416667\\pi$
$480$00
$481$00
$482$1.00000+1.00000i1.00000+1.00000i
$483$00
$484$1.00000i1.00000i
$485$−1.73205+1.00000i−1.73205+1.00000i
$486$00
$487$000.9659260.258819i$-0.0833333\\pi$
−0.965926+0.258819i$0.916667\\pi$
$488$1.36603+0.366025i1.36603+0.366025i
$489$00
$490$00
$491$001.00000i$-0.5\\pi$
1.00000i$0.5\\pi$
$492$00
$493$0.366025+1.36603i0.366025+1.36603i
$494$00
$495$00
$496$00
$497$00
$498$00
$499$000.2588190.965926i$-0.416667\\pi$
−0.258819+0.965926i$0.583333\\pi$
$500$00
$501$00
$502$00
$503$00−0.7071070.707107i$-0.750000\\pi$
0.707107+0.707107i$0.250000\\pi$
$504$00
$505$00
$506$00
$507$00
$508$00
$509$−1.000001.73205i−1.000001.73205i−0.5000000.866025i$-0.666667\\pi$
−0.5000000.866025i$-0.666667\\pi$
$510$00
$511$00
$512$1.00000i1.00000i
$513$00
$514$−1.00000+1.73205i−1.00000+1.73205i
$515$00
$516$00
$517$00
$518$00
$519$00
$520$00
$521$1.366030.366025i1.366030.366025i0.5000000.866025i$-0.333333\\pi$
0.866025+0.500000i$0.166667\\pi$
$522$−0.3660251.36603i−0.3660251.36603i
$523$00−0.5000000.866025i$-0.666667\\pi$
0.500000+0.866025i$0.333333\\pi$
$524$00
$525$00
$526$00
$527$00
$528$00
$529$−0.8660250.500000i−0.8660250.500000i
$530$00
$531$00
$532$00
$533$00
$534$00
$535$00
$536$00
$537$00
$538$−1.000001.00000i−1.000001.00000i
$539$00
$540$00
$541$1.36603+0.366025i1.36603+0.366025i0.8660250.500000i$-0.166667\\pi$
0.500000+0.866025i$0.333333\\pi$
$542$00
$543$00
$544$−0.866025+0.500000i−0.866025+0.500000i
$545$−2.00000−2.00000
$546$00
$547$000.7071070.707107i$-0.250000\\pi$
−0.707107+0.707107i$0.750000\\pi$
$548$00
$549$0.366025+1.36603i0.366025+1.36603i
$550$00
$551$00
$552$00
$553$00
$554$−1.000001.00000i−1.000001.00000i
$555$00
$556$00
$557$00−0.8660250.500000i$-0.833333\\pi$
0.866025+0.500000i$0.166667\\pi$
$558$00
$559$00
$560$00
$561$00
$562$00
$563$00−0.8660250.500000i$-0.833333\\pi$
0.866025+0.500000i$0.166667\\pi$
$564$00
$565$1.00000+1.73205i1.00000+1.73205i
$566$00
$567$00
$568$00
$569$00−0.5000000.866025i$-0.666667\\pi$
0.500000+0.866025i$0.333333\\pi$
$570$00
$571$000.9659260.258819i$-0.0833333\\pi$
−0.965926+0.258819i$0.916667\\pi$
$572$00
$573$00
$574$00
$575$00
$576$0.8660250.500000i0.8660250.500000i
$577$00−0.8660250.500000i$-0.833333\\pi$
0.866025+0.500000i$0.166667\\pi$
$578$0.866025+0.500000i0.866025+0.500000i
$579$00
$580$2.00000i2.00000i
$581$00
$582$00
$583$00
$584$1.366030.366025i1.366030.366025i
$585$00
$586$−1.73205+1.00000i−1.73205+1.00000i
$587$001.00000i$-0.5\\pi$
1.00000i$0.5\\pi$
$588$00
$589$00
$590$00
$591$00
$592$−0.3660251.36603i−0.3660251.36603i
$593$00−0.5000000.866025i$-0.666667\\pi$
0.500000+0.866025i$0.333333\\pi$
$594$00
$595$00
$596$−2.00000−2.00000
$597$00
$598$00
$599$000.5000000.866025i$-0.333333\\pi$
−0.500000+0.866025i$0.666667\\pi$
$600$00
$601$−1.000001.00000i−1.000001.00000i1.00000i$-0.5\\pi$
−1.00000$\\pi$
$602$00
$603$00
$604$00
$605$−1.36603+0.366025i−1.36603+0.366025i
$606$00
$607$00−0.9659260.258819i$-0.916667\\pi$
0.965926+0.258819i$0.0833333\\pi$
$608$00
$609$00
$610$2.00000i2.00000i
$611$00
$612$−0.8660250.500000i−0.8660250.500000i
$613$−1.00000+1.73205i−1.00000+1.73205i−0.500000+0.866025i$0.666667\\pi$
−0.500000+0.866025i$0.666667\\pi$
$614$00
$615$00
$616$00
$617$−1.00000+1.00000i−1.00000+1.00000i1.00000i$0.5\\pi$
−1.00000$\\pi$
$618$00
$619$000.9659260.258819i$-0.0833333\\pi$
−0.965926+0.258819i$0.916667\\pi$
$620$00
$621$00
$622$00
$623$00
$624$00
$625$−0.5000000.866025i−0.5000000.866025i
$626$−0.3660251.36603i−0.3660251.36603i
$627$00
$628$−1.000001.73205i−1.000001.73205i
$629$−1.00000+1.00000i−1.00000+1.00000i
$630$00
$631$001.00000i$-0.5\\pi$
1.00000i$0.5\\pi$
$632$00
$633$00
$634$0.366025+1.36603i0.366025+1.36603i
$635$00
$636$00
$637$00
$638$00
$639$00
$640$−1.36603+0.366025i−1.36603+0.366025i
$641$−0.3660251.36603i−0.3660251.36603i−0.8660250.500000i$-0.833333\\pi$
0.5000000.866025i$-0.333333\\pi$
$642$00
$643$000.7071070.707107i$-0.250000\\pi$
−0.707107+0.707107i$0.750000\\pi$
$644$00
$645$00
$646$00
$647$000.5000000.866025i$-0.333333\\pi$
−0.500000+0.866025i$0.666667\\pi$
$648$0.866025+0.500000i0.866025+0.500000i
$649$00
$650$00
$651$00
$652$00
$653$0.3660251.36603i0.3660251.36603i−0.5000000.866025i$-0.666667\\pi$
0.8660250.500000i$-0.166667\\pi$
$654$00
$655$00
$656$−0.366025+1.36603i−0.366025+1.36603i
$657$1.00000+1.00000i1.00000+1.00000i
$658$00
$659$001.00000$0$
−1.00000$\\pi$
$660$00
$661$000.5000000.866025i$-0.333333\\pi$
−0.500000+0.866025i$0.666667\\pi$
$662$00
$663$00
$664$00
$665$00
$666$1.000001.00000i1.000001.00000i
$667$00
$668$00
$669$00
$670$00
$671$00
$672$00
$673$−1.000001.00000i−1.000001.00000i1.00000i$-0.5\\pi$
−1.00000$\\pi$
$674$−0.366025+1.36603i−0.366025+1.36603i
$675$00
$676$−0.500000+0.866025i−0.500000+0.866025i
$677$1.36603+0.366025i1.36603+0.366025i0.8660250.500000i$-0.166667\\pi$
0.500000+0.866025i$0.333333\\pi$
$678$00
$679$00
$680$1.00000+1.00000i1.00000+1.00000i
$681$00
$682$00
$683$00−0.2588190.965926i$-0.583333\\pi$
0.258819+0.965926i$0.416667\\pi$
$684$00
$685$00
$686$00
$687$00
$688$00
$689$00
$690$00
$691$000.2588190.965926i$-0.416667\\pi$
−0.258819+0.965926i$0.583333\\pi$
$692$1.000001.00000i1.000001.00000i
$693$00
$694$00
$695$00
$696$00
$697$1.366030.366025i1.366030.366025i
$698$00
$699$00
$700$00
$701$001.00000i$-0.5\\pi$
1.00000i$0.5\\pi$
$702$00
$703$00
$704$00
$705$00
$706$2.00000i2.00000i
$707$00
$708$00
$709$−1.366030.366025i−1.366030.366025i−0.5000000.866025i$-0.666667\\pi$
−0.866025+0.500000i$0.833333\\pi$
$710$00
$711$00
$712$00
$713$00
$714$00
$715$00
$716$00
$717$00
$718$00
$719$00−0.9659260.258819i$-0.916667\\pi$
0.965926+0.258819i$0.0833333\\pi$
$720$−1.000001.00000i−1.000001.00000i
$721$00
$722$1.00000i1.00000i
$723$00
$724$1.366030.366025i1.366030.366025i
$725$1.366030.366025i1.366030.366025i
$726$00
$727$001.00000$0$
−1.00000$\\pi$
$728$00
$729$1.00000i1.00000i
$730$−1.000001.73205i−1.000001.73205i
$731$00
$732$00
$733$00−0.5000000.866025i$-0.666667\\pi$
0.500000+0.866025i$0.333333\\pi$
$734$00
$735$00
$736$00
$737$00
$738$−1.36603+0.366025i−1.36603+0.366025i
$739$00−0.8660250.500000i$-0.833333\\pi$
0.866025+0.500000i$0.166667\\pi$
$740$−1.73205+1.00000i−1.73205+1.00000i
$741$00
$742$00
$743$000.7071070.707107i$-0.250000\\pi$
−0.707107+0.707107i$0.750000\\pi$
$744$00
$745$0.732051+2.73205i0.732051+2.73205i
$746$00
$747$00
$748$00
$749$00
$750$00
$751$00−0.9659260.258819i$-0.916667\\pi$
0.965926+0.258819i$0.0833333\\pi$
$752$00
$753$00
$754$00
$755$00
$756$00
$757$2.00000i2.00000i1.00000i$0.5\\pi$
1.00000i$0.5\\pi$
$758$00
$759$00
$760$00
$761$000.8660250.500000i$-0.166667\\pi$
−0.866025+0.500000i$0.833333\\pi$
$762$00
$763$00
$764$00
$765$−0.366025+1.36603i−0.366025+1.36603i
$766$00
$767$00
$768$00
$769$001.00000i$-0.5\\pi$
1.00000i$0.5\\pi$
$770$00
$771$00
$772$−0.366025+1.36603i−0.366025+1.36603i
$773$−1.732051.00000i−1.732051.00000i−0.8660250.500000i$-0.833333\\pi$
−0.8660250.500000i$-0.833333\\pi$
$774$00
$775$00
$776$1.00000+1.00000i1.00000+1.00000i
$777$00
$778$2.000002.00000
$779$00
$780$00
$781$00
$782$00
$783$00
$784$00
$785$−2.00000+2.00000i−2.00000+2.00000i
$786$00
$787$00−0.2588190.965926i$-0.583333\\pi$
0.258819+0.965926i$0.416667\\pi$
$788$1.366030.366025i1.366030.366025i
$789$00
$790$00
$791$00
$792$00
$793$00
$794$0.366025+1.36603i0.366025+1.36603i
$795$00
$796$00
$797$001.00000$0$
−1.00000$\\pi$
$798$00
$799$00
$800$0.500000+0.866025i0.500000+0.866025i
$801$00
$802$0.366025+1.36603i0.366025+1.36603i
$803$00
$804$00
$805$00
$806$00
$807$00
$808$00
$809$1.366030.366025i1.366030.366025i0.5000000.866025i$-0.333333\\pi$
0.866025+0.500000i$0.166667\\pi$
$810$0.3660251.36603i0.3660251.36603i
$811$000.7071070.707107i$-0.250000\\pi$
−0.707107+0.707107i$0.750000\\pi$
$812$00
$813$00
$814$00
$815$00
$816$00
$817$00
$818$2.00000i2.00000i
$819$00
$820$2.000002.00000
$821$−1.366030.366025i−1.366030.366025i−0.5000000.866025i$-0.666667\\pi$
−0.866025+0.500000i$0.833333\\pi$
$822$00
$823$000.9659260.258819i$-0.0833333\\pi$
−0.965926+0.258819i$0.916667\\pi$
$824$00
$825$00
$826$00
$827$00−0.7071070.707107i$-0.750000\\pi$
0.707107+0.707107i$0.250000\\pi$
$828$00
$829$1.000001.73205i1.000001.73205i0.5000000.866025i$-0.333333\\pi$
0.5000000.866025i$-0.333333\\pi$
$830$00
$831$00
$832$00
$833$00
$834$00
$835$00
$836$00
$837$00
$838$00
$839$00−0.7071070.707107i$-0.750000\\pi$
0.707107+0.707107i$0.250000\\pi$
$840$00
$841$1.00000i1.00000i
$842$00
$843$00
$844$00
$845$1.36603+0.366025i1.36603+0.366025i
$846$00
$847$00
$848$00
$849$00
$850$0.5000000.866025i0.5000000.866025i
$851$00
$852$00
$853$1.000001.00000i1.000001.00000i1.00000i$-0.5\\pi$
1.00000$0$
$854$00
$855$00
$856$00
$857$1.366030.366025i1.366030.366025i0.5000000.866025i$-0.333333\\pi$
0.866025+0.500000i$0.166667\\pi$
$858$00
$859$000.8660250.500000i$-0.166667\\pi$
−0.866025+0.500000i$0.833333\\pi$
$860$00
$861$00
$862$00
$863$00−0.5000000.866025i$-0.666667\\pi$
0.500000+0.866025i$0.333333\\pi$
$864$00
$865$−1.732051.00000i−1.732051.00000i
$866$−1.000001.73205i−1.000001.73205i
$867$00
$868$00
$869$00
$870$00
$871$00
$872$0.366025+1.36603i0.366025+1.36603i
$873$−0.366025+1.36603i−0.366025+1.36603i
$874$00
$875$00
$876$00
$877$−0.366025+1.36603i−0.366025+1.36603i0.500000+0.866025i$0.333333\\pi$
−0.866025+0.500000i$0.833333\\pi$
$878$00
$879$00
$880$00
$881$−1.00000+1.00000i−1.00000+1.00000i1.00000i$0.5\\pi$
−1.00000$\\pi$
$882$00
$883$001.00000$0$
−1.00000$\\pi$
$884$00
$885$00
$886$00
$887$00−0.9659260.258819i$-0.916667\\pi$
0.965926+0.258819i$0.0833333\\pi$
$888$00
$889$00
$890$00
$891$00
$892$00
$893$00
$894$00
$895$00
$896$00
$897$00
$898$1.36603+0.366025i1.36603+0.366025i
$899$00
$900$−0.500000+0.866025i−0.500000+0.866025i
$901$00
$902$00
$903$00
$904$1.000001.00000i1.000001.00000i
$905$−1.000001.73205i−1.000001.73205i
$906$00
$907$000.9659260.258819i$-0.0833333\\pi$
−0.965926+0.258819i$0.916667\\pi$
$908$00
$909$00
$910$00
$911$00−0.7071070.707107i$-0.750000\\pi$
0.707107+0.707107i$0.250000\\pi$
$912$00
$913$00
$914$1.000001.73205i1.000001.73205i
$915$00
$916$2.00000i2.00000i
$917$00
$918$00
$919$00−0.5000000.866025i$-0.666667\\pi$
0.500000+0.866025i$0.333333\\pi$
$920$00
$921$00
$922$00
$923$00
$924$00
$925$1.00000+1.00000i1.00000+1.00000i
$926$00
$927$00
$928$1.366030.366025i1.366030.366025i
$929$−0.366025+1.36603i−0.366025+1.36603i0.500000+0.866025i$0.333333\\pi$
−0.866025+0.500000i$0.833333\\pi$
$930$00
$931$00
$932$1.000001.00000i1.000001.00000i
$933$00
$934$00
$935$00
$936$00
$937$001.00000$0$
−1.00000$\\pi$
$938$00
$939$00
$940$00
$941$1.366030.366025i1.366030.366025i0.5000000.866025i$-0.333333\\pi$
0.866025+0.500000i$0.166667\\pi$
$942$00
$943$00
$944$00
$945$00
$946$00
$947$00−0.9659260.258819i$-0.916667\\pi$
0.965926+0.258819i$0.0833333\\pi$
$948$00
$949$00
$950$00
$951$00
$952$00
$953$001.00000i$-0.5\\pi$
1.00000i$0.5\\pi$
$954$00
$955$00
$956$00
$957$00
$958$00
$959$00
$960$00
$961$−0.866025+0.500000i−0.866025+0.500000i
$962$00
$963$00
$964$−1.366030.366025i−1.366030.366025i
$965$2.000002.00000
$966$00
$967$001.00000i$-0.5\\pi$
1.00000i$0.5\\pi$
$968$0.500000+0.866025i0.500000+0.866025i
$969$00
$970$1.000001.73205i1.000001.73205i
$971$000.8660250.500000i$-0.166667\\pi$
−0.866025+0.500000i$0.833333\\pi$
$972$00
$973$00
$974$00
$975$00
$976$−1.36603+0.366025i−1.36603+0.366025i
$977$000.5000000.866025i$-0.333333\\pi$
−0.500000+0.866025i$0.666667\\pi$
$978$00
$979$00
$980$00
$981$−1.00000+1.00000i−1.00000+1.00000i
$982$00
$983$00−0.2588190.965926i$-0.583333\\pi$
0.258819+0.965926i$0.416667\\pi$
$984$00
$985$−1.000001.73205i−1.000001.73205i
$986$−1.000001.00000i−1.000001.00000i
$987$00
$988$00
$989$00
$990$00
$991$00−0.2588190.965926i$-0.583333\\pi$
0.258819+0.965926i$0.416667\\pi$
$992$00
$993$00
$994$00
$995$00
$996$00
$997$1.366030.366025i1.366030.366025i0.5000000.866025i$-0.333333\\pi$
0.866025+0.500000i$0.166667\\pi$
$998$00
$999$00
\n\n(See $a_n$ instead)(See $a_n$ instead)(See $a_n$ instead)(See only $a_p$ )(See only $a_p$ )(See only $a_p$ )\n\n
       By twisting character
CharParityOrdTypeTwistMinDim
1.1even1trivial3332.1.bc.b.2027.14
4.3odd2CM3332.1.bc.b.2027.14
7.2even3inner3332.1.bc.b.667.14
7.3odd668.1.f.a.55.1yes2
7.4even33332.1.m.b.2843.12
7.5odd63332.1.bc.c.667.14
7.6odd23332.1.bc.c.2027.14
17.13even4inner3332.1.bc.b.2223.14
21.17even6612.1.l.a.55.12
28.3even668.1.f.a.55.1yes2
28.11odd63332.1.m.b.2843.12
28.19even63332.1.bc.c.667.14
28.23odd6inner3332.1.bc.b.667.14
28.27even23332.1.bc.c.2027.14
35.3even121700.1.n.a.599.12
35.17even121700.1.n.b.599.12
35.24odd61700.1.p.a.1551.12
56.3even61088.1.p.a.191.12
56.45odd61088.1.p.a.191.12
68.47odd4inner3332.1.bc.b.2223.14
84.59odd6612.1.l.a.55.12
119.3even481156.1.g.b.155.18
119.10even481156.1.g.b.179.18
119.13odd43332.1.bc.c.2223.14
119.24even481156.1.g.b.179.28
119.30even12inner3332.1.bc.b.863.14
119.31even481156.1.g.b.155.28
119.38odd121156.1.f.b.251.12
119.45even481156.1.g.b.399.18
119.47odd123332.1.bc.c.863.14
119.59odd241156.1.c.b.579.12
119.66odd241156.1.d.a.1155.22
119.73even481156.1.g.b.423.28
119.80even481156.1.g.b.423.18
119.81even123332.1.m.b.3039.12
119.87odd241156.1.d.a.1155.12
119.94odd241156.1.c.b.579.22
119.101odd61156.1.f.b.327.12
119.108even481156.1.g.b.399.28
119.115odd1268.1.f.a.47.12
140.3odd121700.1.n.a.599.12
140.59even61700.1.p.a.1551.12
140.87odd121700.1.n.b.599.12
357.353even12612.1.l.a.523.12
476.3odd481156.1.g.b.155.18
476.31odd481156.1.g.b.155.28
476.47even123332.1.bc.c.863.14
476.59even241156.1.c.b.579.12
476.87even241156.1.d.a.1155.12
476.115even1268.1.f.a.47.12
476.143odd481156.1.g.b.179.28
476.199odd481156.1.g.b.423.18
476.227odd481156.1.g.b.399.28
476.251even43332.1.bc.c.2223.14
476.283odd481156.1.g.b.399.18
476.311odd481156.1.g.b.423.28
476.319odd123332.1.m.b.3039.12
476.339even61156.1.f.b.327.12
476.367odd481156.1.g.b.179.18
476.387odd12inner3332.1.bc.b.863.14
476.395even121156.1.f.b.251.12
476.423even241156.1.d.a.1155.22
476.451even241156.1.c.b.579.22
595.234odd121700.1.p.a.251.12
595.353even121700.1.n.b.999.12
595.472even121700.1.n.a.999.12
952.115even121088.1.p.a.319.12
952.829odd121088.1.p.a.319.12
1428.1067odd12612.1.l.a.523.12
2380.1067odd121700.1.n.a.999.12
2380.1543odd121700.1.n.b.999.12
2380.2019even121700.1.p.a.251.12
\n\n
        By twisted newform
TwistMinDimCharParityOrdType
68.1.f.a.47.12119.115odd12
68.1.f.a.47.12476.115even12
68.1.f.a.55.1yes27.3odd6
68.1.f.a.55.1yes228.3even6
612.1.l.a.55.1221.17even6
612.1.l.a.55.1284.59odd6
612.1.l.a.523.12357.353even12
612.1.l.a.523.121428.1067odd12
1088.1.p.a.191.1256.3even6
1088.1.p.a.191.1256.45odd6
1088.1.p.a.319.12952.115even12
1088.1.p.a.319.12952.829odd12
1156.1.c.b.579.12119.59odd24
1156.1.c.b.579.12476.59even24
1156.1.c.b.579.22119.94odd24
1156.1.c.b.579.22476.451even24
1156.1.d.a.1155.12119.87odd24
1156.1.d.a.1155.12476.87even24
1156.1.d.a.1155.22119.66odd24
1156.1.d.a.1155.22476.423even24
1156.1.f.b.251.12119.38odd12
1156.1.f.b.251.12476.395even12
1156.1.f.b.327.12119.101odd6
1156.1.f.b.327.12476.339even6
1156.1.g.b.155.18119.3even48
1156.1.g.b.155.18476.3odd48
1156.1.g.b.155.28119.31even48
1156.1.g.b.155.28476.31odd48
1156.1.g.b.179.18119.10even48
1156.1.g.b.179.18476.367odd48
1156.1.g.b.179.28119.24even48
1156.1.g.b.179.28476.143odd48
1156.1.g.b.399.18119.45even48
1156.1.g.b.399.18476.283odd48
1156.1.g.b.399.28119.108even48
1156.1.g.b.399.28476.227odd48
1156.1.g.b.423.18119.80even48
1156.1.g.b.423.18476.199odd48
1156.1.g.b.423.28119.73even48
1156.1.g.b.423.28476.311odd48
1700.1.n.a.599.1235.3even12
1700.1.n.a.599.12140.3odd12
1700.1.n.a.999.12595.472even12
1700.1.n.a.999.122380.1067odd12
1700.1.n.b.599.1235.17even12
1700.1.n.b.599.12140.87odd12
1700.1.n.b.999.12595.353even12
1700.1.n.b.999.122380.1543odd12
1700.1.p.a.251.12595.234odd12
1700.1.p.a.251.122380.2019even12
1700.1.p.a.1551.1235.24odd6
1700.1.p.a.1551.12140.59even6
3332.1.m.b.2843.127.4even3
3332.1.m.b.2843.1228.11odd6
3332.1.m.b.3039.12119.81even12
3332.1.m.b.3039.12476.319odd12
3332.1.bc.b.667.147.2even3inner
3332.1.bc.b.667.1428.23odd6inner
3332.1.bc.b.863.14119.30even12inner
3332.1.bc.b.863.14476.387odd12inner
3332.1.bc.b.2027.141.1even1trivial
3332.1.bc.b.2027.144.3odd2CM
3332.1.bc.b.2223.1417.13even4inner
3332.1.bc.b.2223.1468.47odd4inner
3332.1.bc.c.667.147.5odd6
3332.1.bc.c.667.1428.19even6
3332.1.bc.c.863.14119.47odd12
3332.1.bc.c.863.14476.47even12
3332.1.bc.c.2027.147.6odd2
3332.1.bc.c.2027.1428.27even2
3332.1.bc.c.2223.14119.13odd4
3332.1.bc.c.2223.14476.251even4
\n", "main_html": "
\n
\n
\n \n
\n Show commands:\n Magma\n / PariGP\n / SageMath\n
\n\n\n\n\n\n\n\n
[N,k,chi] = [3332,1,Mod(667,3332)]
 
mf = mfinit([N,k,chi],0)
 
lf = mfeigenbasis(mf)
 
\n
from sage.modular.dirichlet import DirichletCharacter
 
H = DirichletGroup(3332, base_ring=CyclotomicField(12))
 
chi = DirichletCharacter(H, H._module([6, 4, 9]))
 
N = Newforms(chi, 1, names=\"a\")
 
\n
//Please install CHIMP (https://github.com/edgarcosta/CHIMP) if you want to run this code
 
chi := DirichletCharacter(\"3332.667\");
 
S:= CuspForms(chi, 1);
 
N := Newforms(S);
 
\n\n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n
Level: \\( N \\) \\(=\\)\\( 3332 = 2^{2} \\cdot 7^{2} \\cdot 17 \\)
Weight: \\( k \\) \\(=\\)\\( 1 \\)
Character orbit: \\([\\chi]\\) \\(=\\) 3332.bc (of order \\(12\\), degree \\(4\\), not minimal)
\n\n

Newform invariants

\n\n\n
sage: f = N[0] # Warning: the index may be different
 
\n
gp: f = lf[1] \\\\ Warning: the index may be different
 
\n\n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\t\n \n \t\n \t\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n
Self dual: no
Analytic conductor: \\(1.66288462209\\)
Analytic rank: \\(0\\)
Dimension: \\(4\\)
Coefficient field: \\(\\Q(\\zeta_{12})\\)
\n \n
gp: f.mod \\\\ as an extension of the character field
 
\n\n
Defining polynomial: \n\n \\( x^{4} - x^{2} + 1 \\)\n \n\n \n \"Copy\n \n \n \"Toggle\n \n
Coefficient ring: \\(\\Z[a_1, a_2]\\)
Coefficient ring index: \\( 1 \\)
Twist minimal: no (minimal twist has level 68)
Projective image:\\(D_{4}\\)
Projective field:Galois closure of 4.2.19652.1
Artin image:$C_4\\wr C_2\\times C_6$
Artin field:Galois closure of \\(\\mathbb{Q}[x]/(x^{48} - \\cdots)\\)
\n\n\n

Embedding invariants

\n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n
Embedding label 2027.1
Root\\(0.866025 - 0.500000i\\) of defining polynomial
Character\\(\\chi\\)\\(=\\)3332.2027
Dual form 3332.1.bc.b.863.1
\n\n\n\n
\n \n
sage: f.q_expansion() # note that sage often uses an isomorphic number field
 
\n
gp: mfcoefs(f, 20)
 
\n\n
\n \n \n \n \n \n \n \n \n \n \n \n
\\(f(q)\\)\\(=\\)\\(q+(-0.866025 + 0.500000i) q^{2} +(0.500000 - 0.866025i) q^{4} +(-1.36603 - 0.366025i) q^{5} +1.00000i q^{8} +(-0.866025 + 0.500000i) q^{9} +(1.36603 - 0.366025i) q^{10} +(-0.500000 - 0.866025i) q^{16} +(-0.500000 + 0.866025i) q^{17} +(0.500000 - 0.866025i) q^{18} +(-1.00000 + 1.00000i) q^{20} +(0.866025 + 0.500000i) q^{25} +(1.00000 - 1.00000i) q^{29} +(0.866025 + 0.500000i) q^{32} -1.00000i q^{34} +1.00000i q^{36} +(1.36603 + 0.366025i) q^{37} +(0.366025 - 1.36603i) q^{40} +(-1.00000 - 1.00000i) q^{41} +(1.36603 - 0.366025i) q^{45} -1.00000 q^{50} +(-0.366025 + 1.36603i) q^{58} +(0.366025 - 1.36603i) q^{61} -1.00000 q^{64} +(0.500000 + 0.866025i) q^{68} +(-0.500000 - 0.866025i) q^{72} +(-0.366025 - 1.36603i) q^{73} +(-1.36603 + 0.366025i) q^{74} +(0.366025 + 1.36603i) q^{80} +(0.500000 - 0.866025i) q^{81} +(1.36603 + 0.366025i) q^{82} +(1.00000 - 1.00000i) q^{85} +(-1.00000 + 1.00000i) q^{90} +(1.00000 - 1.00000i) q^{97} +O(q^{100})\\)
\\(\\operatorname{Tr}(f)(q)\\)\\(=\\)\n\n \\( 4 q + 2 q^{4} - 2 q^{5} + 2 q^{10} - 2 q^{16} - 2 q^{17} + 2 q^{18} - 4 q^{20} + 4 q^{29} + 2 q^{37} - 2 q^{40} - 4 q^{41} + 2 q^{45} - 4 q^{50} + 2 q^{58} - 2 q^{61} - 4 q^{64} + 2 q^{68} - 2 q^{72} + 2 q^{73}+ \\cdots + 4 q^{97}+O(q^{100}) \\)\n \n\n \n \"Copy\n \n \n \"Toggle\n \n
\n
\n\n
\n\n\n

Character values

\n

We give the values of \\(\\chi\\) on generators for \\(\\left(\\mathbb{Z}/3332\\mathbb{Z}\\right)^\\times\\).

\n\n \n \n \n \n \n \n \n \n \n \n \n \n
\\(n\\)\\(785\\)\\(885\\)\\(1667\\)
\\(\\chi(n)\\)\\(e\\left(\\frac{3}{4}\\right)\\)\\(e\\left(\\frac{2}{3}\\right)\\)\\(-1\\)
\n\n\n

Coefficient data

\n\n

For each \\(n\\) we display the coefficients of the \\(q\\)-expansion \\(a_n\\), the\nSatake parameters \\(\\alpha_p\\),\nand the Satake angles \\(\\theta_p = \\textrm{Arg}(\\alpha_p)\\).

\n\n\n\n\n

\n
\n \n\n \n (See \\(a_n\\) instead)\n \n\n \n (See \\(a_n\\) instead)\n \n\n \n (See \\(a_n\\) instead)\n \n \n\n \n (See only \\(a_p\\))\n \n\n \n (See only \\(a_p\\))\n \n\n \n (See only \\(a_p\\))\n \n
\n\n\n\n\n
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\n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n
\n \\(n\\)\n \n \\(a_n\\)\n \n \\(a_n / n^{(k-1)/2}\\)\n \n \\( \\alpha_n \\)\n \n \\( \\theta_n \\)\n
\n \\(p\\)\n \n \\(a_p\\)\n \n \\(a_p / p^{(k-1)/2}\\)\n \n \\( \\alpha_p\\)\n \n \\( \\theta_p \\)\n
\n \\(2\\)\n \n −0.866025\n \n +\n \n 0.500000i\n \n −0.866025\n \n +\n \n 0.500000i\n \n\n \n\n \n\n \n\n
\n\n \n\n \n\n \n\n
\n \\(3\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.258819\n \n −\n \n 0.965926i\n \n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \n \\(0.416667\\pi\\)\n
\n \\(4\\)\n \n 0.500000\n \n −\n \n 0.866025i\n \n 0.500000\n \n −\n \n 0.866025i\n
\n \\(5\\)\n \n −1.36603\n \n −\n \n 0.366025i\n \n −1.36603\n \n −\n \n 0.366025i\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(6\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(7\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n\n \n\n \n\n
\n\n \n\n \n\n \n\n
\n \\(8\\)\n \n\n \n\n \n 1.00000i\n \n\n \n\n \n 1.00000i\n
\n \\(9\\)\n \n −0.866025\n \n +\n \n 0.500000i\n \n −0.866025\n \n +\n \n 0.500000i\n
\n \\(10\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n
\n \\(11\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.965926\n \n −\n \n 0.258819i\n \n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \n \\(0.916667\\pi\\)\n
\n \\(12\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(13\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(14\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(15\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(16\\)\n \n −0.500000\n \n −\n \n 0.866025i\n \n −0.500000\n \n −\n \n 0.866025i\n
\n \\(17\\)\n \n −0.500000\n \n +\n \n 0.866025i\n \n −0.500000\n \n +\n \n 0.866025i\n \n\n \n\n \n\n \n\n
\n\n \n\n \n\n \n\n
\n \\(18\\)\n \n 0.500000\n \n −\n \n 0.866025i\n \n 0.500000\n \n −\n \n 0.866025i\n
\n \\(19\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(20\\)\n \n −1.00000\n \n +\n \n 1.00000i\n \n −1.00000\n \n +\n \n 1.00000i\n
\n \\(21\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(22\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(23\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.258819\n \n −\n \n 0.965926i\n \n \\(-0.416667\\pi\\)\n
\n −0.258819\n \n +\n \n 0.965926i\n \n \\(0.583333\\pi\\)\n
\n \\(24\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(25\\)\n \n 0.866025\n \n +\n \n 0.500000i\n \n 0.866025\n \n +\n \n 0.500000i\n
\n \\(26\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(27\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(28\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(29\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n \\(30\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(31\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.258819\n \n −\n \n 0.965926i\n \n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \n \\(0.416667\\pi\\)\n
\n \\(32\\)\n \n 0.866025\n \n +\n \n 0.500000i\n \n 0.866025\n \n +\n \n 0.500000i\n
\n \\(33\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(34\\)\n \n\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n
\n \\(35\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(36\\)\n \n\n \n\n \n 1.00000i\n \n\n \n\n \n 1.00000i\n
\n \\(37\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(38\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(39\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(40\\)\n \n 0.366025\n \n −\n \n 1.36603i\n \n 0.366025\n \n −\n \n 1.36603i\n
\n \\(41\\)\n \n −1.00000\n \n −\n \n 1.00000i\n \n −1.00000\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(42\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(43\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(44\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(45\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n
\n \\(46\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(47\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(48\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(49\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(50\\)\n \n −1.00000\n \n\n \n\n \n −1.00000\n \n\n \n\n
\n \\(51\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(52\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(53\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(54\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(55\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(56\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(57\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(58\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n
\n \\(59\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(60\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(61\\)\n \n 0.366025\n \n −\n \n 1.36603i\n \n 0.366025\n \n −\n \n 1.36603i\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n \\(62\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(63\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(64\\)\n \n −1.00000\n \n\n \n\n \n −1.00000\n \n\n \n\n
\n \\(65\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(66\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(67\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(68\\)\n \n 0.500000\n \n +\n \n 0.866025i\n \n 0.500000\n \n +\n \n 0.866025i\n
\n \\(69\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(70\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(71\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.707107\n \n −\n \n 0.707107i\n \n \\(-0.250000\\pi\\)\n
\n −0.707107\n \n +\n \n 0.707107i\n \n \\(0.750000\\pi\\)\n
\n \\(72\\)\n \n −0.500000\n \n −\n \n 0.866025i\n \n −0.500000\n \n −\n \n 0.866025i\n
\n \\(73\\)\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n \\(74\\)\n \n −1.36603\n \n +\n \n 0.366025i\n \n −1.36603\n \n +\n \n 0.366025i\n
\n \\(75\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(76\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(77\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(78\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(79\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.258819\n \n −\n \n 0.965926i\n \n \\(-0.416667\\pi\\)\n
\n −0.258819\n \n +\n \n 0.965926i\n \n \\(0.583333\\pi\\)\n
\n \\(80\\)\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.366025\n \n +\n \n 1.36603i\n
\n \\(81\\)\n \n 0.500000\n \n −\n \n 0.866025i\n \n 0.500000\n \n −\n \n 0.866025i\n
\n \\(82\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n
\n \\(83\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(84\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(85\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n
\n \\(86\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(87\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(88\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(89\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(90\\)\n \n −1.00000\n \n +\n \n 1.00000i\n \n −1.00000\n \n +\n \n 1.00000i\n
\n \\(91\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(92\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(93\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(94\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(95\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(96\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(97\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n \\(98\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(99\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(100\\)\n \n 0.866025\n \n −\n \n 0.500000i\n \n 0.866025\n \n −\n \n 0.500000i\n
\n \\(101\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(102\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(103\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(104\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(105\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(106\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(107\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.965926\n \n −\n \n 0.258819i\n \n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \n \\(0.0833333\\pi\\)\n
\n \\(108\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(109\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(110\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(111\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(112\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(113\\)\n \n −1.00000\n \n −\n \n 1.00000i\n \n −1.00000\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(114\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(115\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(116\\)\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.366025\n \n −\n \n 1.36603i\n
\n \\(117\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(118\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(119\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(120\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(121\\)\n \n 0.866025\n \n −\n \n 0.500000i\n \n 0.866025\n \n −\n \n 0.500000i\n
\n \\(122\\)\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.366025\n \n +\n \n 1.36603i\n
\n \\(123\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(124\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(125\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(126\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(127\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(128\\)\n \n 0.866025\n \n −\n \n 0.500000i\n \n 0.866025\n \n −\n \n 0.500000i\n
\n \\(129\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(130\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(131\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.965926\n \n −\n \n 0.258819i\n \n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \n \\(0.0833333\\pi\\)\n
\n \\(132\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(133\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(134\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(135\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(136\\)\n \n −0.866025\n \n −\n \n 0.500000i\n \n −0.866025\n \n −\n \n 0.500000i\n
\n \\(137\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(138\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(139\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.707107\n \n −\n \n 0.707107i\n \n \\(-0.250000\\pi\\)\n
\n −0.707107\n \n +\n \n 0.707107i\n \n \\(0.750000\\pi\\)\n
\n \\(140\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(141\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(142\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(143\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(144\\)\n \n 0.866025\n \n +\n \n 0.500000i\n \n 0.866025\n \n +\n \n 0.500000i\n
\n \\(145\\)\n \n −1.73205\n \n +\n \n 1.00000i\n \n −1.73205\n \n +\n \n 1.00000i\n
\n \\(146\\)\n \n 1.00000\n \n +\n \n 1.00000i\n \n 1.00000\n \n +\n \n 1.00000i\n
\n \\(147\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(148\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n
\n \\(149\\)\n \n −1.00000\n \n −\n \n 1.73205i\n \n −1.00000\n \n −\n \n 1.73205i\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n \\(150\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(151\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(152\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(153\\)\n \n\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n
\n \\(154\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(155\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(156\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(157\\)\n \n 1.00000\n \n −\n \n 1.73205i\n \n 1.00000\n \n −\n \n 1.73205i\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n \\(158\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(159\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(160\\)\n \n −1.00000\n \n −\n \n 1.00000i\n \n −1.00000\n \n −\n \n 1.00000i\n
\n \\(161\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(162\\)\n \n\n \n\n \n 1.00000i\n \n\n \n\n \n 1.00000i\n
\n \\(163\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.258819\n \n −\n \n 0.965926i\n \n \\(-0.416667\\pi\\)\n
\n −0.258819\n \n +\n \n 0.965926i\n \n \\(0.583333\\pi\\)\n
\n \\(164\\)\n \n −1.36603\n \n +\n \n 0.366025i\n \n −1.36603\n \n +\n \n 0.366025i\n
\n \\(165\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(166\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(167\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.707107\n \n −\n \n 0.707107i\n \n \\(-0.250000\\pi\\)\n
\n −0.707107\n \n +\n \n 0.707107i\n \n \\(0.750000\\pi\\)\n
\n \\(168\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(169\\)\n \n −1.00000\n \n\n \n\n \n −1.00000\n \n\n \n\n
\n \\(170\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n
\n \\(171\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(172\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(173\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(174\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(175\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(176\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(177\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(178\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(179\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(180\\)\n \n 0.366025\n \n −\n \n 1.36603i\n \n 0.366025\n \n −\n \n 1.36603i\n
\n \\(181\\)\n \n 1.00000\n \n +\n \n 1.00000i\n \n 1.00000\n \n +\n \n 1.00000i\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(182\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(183\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(184\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(185\\)\n \n −1.73205\n \n −\n \n 1.00000i\n \n −1.73205\n \n −\n \n 1.00000i\n
\n \\(186\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(187\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(188\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(189\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(190\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(191\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(192\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(193\\)\n \n −1.36603\n \n +\n \n 0.366025i\n \n −1.36603\n \n +\n \n 0.366025i\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(194\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n
\n \\(195\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(196\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(197\\)\n \n 1.00000\n \n +\n \n 1.00000i\n \n 1.00000\n \n +\n \n 1.00000i\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(198\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(199\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.258819\n \n −\n \n 0.965926i\n \n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \n \\(0.416667\\pi\\)\n
\n \\(200\\)\n \n −0.500000\n \n +\n \n 0.866025i\n \n −0.500000\n \n +\n \n 0.866025i\n
\n \\(201\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(202\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(203\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(204\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(205\\)\n \n 1.00000\n \n +\n \n 1.73205i\n \n 1.00000\n \n +\n \n 1.73205i\n
\n \\(206\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(207\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(208\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(209\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(210\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(211\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.707107\n \n −\n \n 0.707107i\n \n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \n \\(0.250000\\pi\\)\n
\n \\(212\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(213\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(214\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(215\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(216\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(217\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(218\\)\n \n −1.00000\n \n +\n \n 1.00000i\n \n −1.00000\n \n +\n \n 1.00000i\n
\n \\(219\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(220\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(221\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(222\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(223\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(224\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(225\\)\n \n −1.00000\n \n\n \n\n \n −1.00000\n \n\n \n\n
\n \\(226\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n
\n \\(227\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.965926\n \n −\n \n 0.258819i\n \n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \n \\(0.916667\\pi\\)\n
\n \\(228\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(229\\)\n \n −1.73205\n \n +\n \n 1.00000i\n \n −1.73205\n \n +\n \n 1.00000i\n \n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(230\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(231\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(232\\)\n \n 1.00000\n \n +\n \n 1.00000i\n \n 1.00000\n \n +\n \n 1.00000i\n
\n \\(233\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(234\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(235\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(236\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(237\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(238\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(239\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(240\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(241\\)\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n \\(242\\)\n \n −0.500000\n \n +\n \n 0.866025i\n \n −0.500000\n \n +\n \n 0.866025i\n
\n \\(243\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(244\\)\n \n −1.00000\n \n −\n \n 1.00000i\n \n −1.00000\n \n −\n \n 1.00000i\n
\n \\(245\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(246\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(247\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(248\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(249\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(250\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(251\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(252\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(253\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(254\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(255\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(256\\)\n \n −0.500000\n \n +\n \n 0.866025i\n \n −0.500000\n \n +\n \n 0.866025i\n
\n \\(257\\)\n \n 1.73205\n \n −\n \n 1.00000i\n \n 1.73205\n \n −\n \n 1.00000i\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n \\(258\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(259\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(260\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(261\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n
\n \\(262\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(263\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(264\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(265\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(266\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(267\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(268\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(269\\)\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(270\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(271\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(272\\)\n \n 1.00000\n \n\n \n\n \n 1.00000\n \n\n \n\n
\n \\(273\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(274\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(275\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(276\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(277\\)\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(278\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(279\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(280\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(281\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(282\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(283\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.965926\n \n −\n \n 0.258819i\n \n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \n \\(0.916667\\pi\\)\n
\n \\(284\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(285\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(286\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(287\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(288\\)\n \n −1.00000\n \n\n \n\n \n −1.00000\n \n\n \n\n
\n \\(289\\)\n \n −0.500000\n \n −\n \n 0.866025i\n \n −0.500000\n \n −\n \n 0.866025i\n
\n \\(290\\)\n \n 1.00000\n \n −\n \n 1.73205i\n \n 1.00000\n \n −\n \n 1.73205i\n
\n \\(291\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(292\\)\n \n −1.36603\n \n −\n \n 0.366025i\n \n −1.36603\n \n −\n \n 0.366025i\n
\n \\(293\\)\n \n 2.00000\n \n\n \n\n \n 2.00000\n \n\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n \\(294\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(295\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(296\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n
\n \\(297\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(298\\)\n \n 1.73205\n \n +\n \n 1.00000i\n \n 1.73205\n \n +\n \n 1.00000i\n
\n \\(299\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(300\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(301\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(302\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(303\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(304\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(305\\)\n \n −1.00000\n \n +\n \n 1.73205i\n \n −1.00000\n \n +\n \n 1.73205i\n
\n \\(306\\)\n \n 0.500000\n \n +\n \n 0.866025i\n \n 0.500000\n \n +\n \n 0.866025i\n
\n \\(307\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(308\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(309\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(310\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(311\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.258819\n \n −\n \n 0.965926i\n \n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \n \\(0.416667\\pi\\)\n
\n \\(312\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(313\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n \n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(314\\)\n \n\n \n\n \n 2.00000i\n \n\n \n\n \n 2.00000i\n
\n \\(315\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(316\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(317\\)\n \n 0.366025\n \n −\n \n 1.36603i\n \n 0.366025\n \n −\n \n 1.36603i\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n \\(318\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(319\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(320\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n
\n \\(321\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(322\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(323\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(324\\)\n \n −0.500000\n \n −\n \n 0.866025i\n \n −0.500000\n \n −\n \n 0.866025i\n
\n \\(325\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(326\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(327\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(328\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n
\n \\(329\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(330\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(331\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(332\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(333\\)\n \n −1.36603\n \n +\n \n 0.366025i\n \n −1.36603\n \n +\n \n 0.366025i\n
\n \\(334\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(335\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(336\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(337\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n \\(338\\)\n \n 0.866025\n \n −\n \n 0.500000i\n \n 0.866025\n \n −\n \n 0.500000i\n
\n \\(339\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(340\\)\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.366025\n \n −\n \n 1.36603i\n
\n \\(341\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(342\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(343\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(344\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(345\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(346\\)\n \n −1.36603\n \n +\n \n 0.366025i\n \n −1.36603\n \n +\n \n 0.366025i\n
\n \\(347\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.965926\n \n −\n \n 0.258819i\n \n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \n \\(0.916667\\pi\\)\n
\n \\(348\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(349\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(350\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(351\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(352\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(353\\)\n \n −1.00000\n \n +\n \n 1.73205i\n \n −1.00000\n \n +\n \n 1.73205i\n \n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(354\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(355\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(356\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(357\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(358\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(359\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(360\\)\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.366025\n \n +\n \n 1.36603i\n
\n \\(361\\)\n \n 0.500000\n \n −\n \n 0.866025i\n \n 0.500000\n \n −\n \n 0.866025i\n
\n \\(362\\)\n \n −1.36603\n \n −\n \n 0.366025i\n \n −1.36603\n \n −\n \n 0.366025i\n
\n \\(363\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(364\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(365\\)\n \n\n \n\n \n 2.00000i\n \n\n \n\n \n 2.00000i\n
\n \\(366\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(367\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.965926\n \n −\n \n 0.258819i\n \n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \n \\(0.916667\\pi\\)\n
\n \\(368\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(369\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n
\n \\(370\\)\n \n 2.00000\n \n\n \n\n \n 2.00000\n \n\n \n\n
\n \\(371\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(372\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(373\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(374\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(375\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(376\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(377\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(378\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(379\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.707107\n \n −\n \n 0.707107i\n \n \\(-0.250000\\pi\\)\n
\n −0.707107\n \n +\n \n 0.707107i\n \n \\(0.750000\\pi\\)\n
\n \\(380\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(381\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(382\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(383\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(384\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(385\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(386\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n
\n \\(387\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(388\\)\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.366025\n \n −\n \n 1.36603i\n
\n \\(389\\)\n \n −1.73205\n \n −\n \n 1.00000i\n \n −1.73205\n \n −\n \n 1.00000i\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n \\(390\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(391\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(392\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(393\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(394\\)\n \n −1.36603\n \n −\n \n 0.366025i\n \n −1.36603\n \n −\n \n 0.366025i\n
\n \\(395\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(396\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(397\\)\n \n 0.366025\n \n −\n \n 1.36603i\n \n 0.366025\n \n −\n \n 1.36603i\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n \\(398\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(399\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(400\\)\n \n\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n
\n \\(401\\)\n \n 0.366025\n \n −\n \n 1.36603i\n \n 0.366025\n \n −\n \n 1.36603i\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n \\(402\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(403\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(404\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(405\\)\n \n −1.00000\n \n +\n \n 1.00000i\n \n −1.00000\n \n +\n \n 1.00000i\n
\n \\(406\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(407\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(408\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(409\\)\n \n −1.00000\n \n +\n \n 1.73205i\n \n −1.00000\n \n +\n \n 1.73205i\n \n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(410\\)\n \n −1.73205\n \n −\n \n 1.00000i\n \n −1.73205\n \n −\n \n 1.00000i\n
\n \\(411\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(412\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(413\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(414\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(415\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(416\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(417\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(418\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(419\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.707107\n \n −\n \n 0.707107i\n \n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \n \\(0.250000\\pi\\)\n
\n \\(420\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(421\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(422\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(423\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(424\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(425\\)\n \n −0.866025\n \n +\n \n 0.500000i\n \n −0.866025\n \n +\n \n 0.500000i\n
\n \\(426\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(427\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(428\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(429\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(430\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(431\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.965926\n \n −\n \n 0.258819i\n \n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \n \\(0.916667\\pi\\)\n
\n \\(432\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(433\\)\n \n\n \n\n \n 2.00000i\n \n\n \n\n \n 2.00000i\n \n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(434\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(435\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(436\\)\n \n 0.366025\n \n −\n \n 1.36603i\n \n 0.366025\n \n −\n \n 1.36603i\n
\n \\(437\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(438\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(439\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.965926\n \n −\n \n 0.258819i\n \n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \n \\(0.0833333\\pi\\)\n
\n \\(440\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(441\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(442\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(443\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(444\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(445\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(446\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(447\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(448\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(449\\)\n \n −1.00000\n \n −\n \n 1.00000i\n \n −1.00000\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(450\\)\n \n 0.866025\n \n −\n \n 0.500000i\n \n 0.866025\n \n −\n \n 0.500000i\n
\n \\(451\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(452\\)\n \n −1.36603\n \n +\n \n 0.366025i\n \n −1.36603\n \n +\n \n 0.366025i\n
\n \\(453\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(454\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(455\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(456\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(457\\)\n \n −1.73205\n \n +\n \n 1.00000i\n \n −1.73205\n \n +\n \n 1.00000i\n \n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(458\\)\n \n 1.00000\n \n −\n \n 1.73205i\n \n 1.00000\n \n −\n \n 1.73205i\n
\n \\(459\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(460\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(461\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(462\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(463\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(464\\)\n \n −1.36603\n \n −\n \n 0.366025i\n \n −1.36603\n \n −\n \n 0.366025i\n
\n \\(465\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(466\\)\n \n −1.36603\n \n +\n \n 0.366025i\n \n −1.36603\n \n +\n \n 0.366025i\n
\n \\(467\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(468\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(469\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(470\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(471\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(472\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(473\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(474\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(475\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(476\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(477\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(478\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(479\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.258819\n \n −\n \n 0.965926i\n \n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \n \\(0.416667\\pi\\)\n
\n \\(480\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(481\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(482\\)\n \n 1.00000\n \n +\n \n 1.00000i\n \n 1.00000\n \n +\n \n 1.00000i\n
\n \\(483\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(484\\)\n \n\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n
\n \\(485\\)\n \n −1.73205\n \n +\n \n 1.00000i\n \n −1.73205\n \n +\n \n 1.00000i\n
\n \\(486\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(487\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.965926\n \n −\n \n 0.258819i\n \n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \n \\(0.916667\\pi\\)\n
\n \\(488\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n
\n \\(489\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(490\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(491\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(492\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(493\\)\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.366025\n \n +\n \n 1.36603i\n
\n \\(494\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(495\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(496\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(497\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(498\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(499\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.258819\n \n −\n \n 0.965926i\n \n \\(-0.416667\\pi\\)\n
\n −0.258819\n \n +\n \n 0.965926i\n \n \\(0.583333\\pi\\)\n
\n \\(500\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(501\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(502\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(503\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.707107\n \n −\n \n 0.707107i\n \n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \n \\(0.250000\\pi\\)\n
\n \\(504\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(505\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(506\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(507\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(508\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(509\\)\n \n −1.00000\n \n −\n \n 1.73205i\n \n −1.00000\n \n −\n \n 1.73205i\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n \\(510\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(511\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(512\\)\n \n\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n
\n \\(513\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(514\\)\n \n −1.00000\n \n +\n \n 1.73205i\n \n −1.00000\n \n +\n \n 1.73205i\n
\n \\(515\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(516\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(517\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(518\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(519\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(520\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(521\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(522\\)\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.366025\n \n −\n \n 1.36603i\n
\n \\(523\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(524\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(525\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(526\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(527\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(528\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(529\\)\n \n −0.866025\n \n −\n \n 0.500000i\n \n −0.866025\n \n −\n \n 0.500000i\n
\n \\(530\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(531\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(532\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(533\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(534\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(535\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(536\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(537\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(538\\)\n \n −1.00000\n \n −\n \n 1.00000i\n \n −1.00000\n \n −\n \n 1.00000i\n
\n \\(539\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(540\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(541\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(542\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(543\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(544\\)\n \n −0.866025\n \n +\n \n 0.500000i\n \n −0.866025\n \n +\n \n 0.500000i\n
\n \\(545\\)\n \n −2.00000\n \n\n \n\n \n −2.00000\n \n\n \n\n
\n \\(546\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(547\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.707107\n \n −\n \n 0.707107i\n \n \\(-0.250000\\pi\\)\n
\n −0.707107\n \n +\n \n 0.707107i\n \n \\(0.750000\\pi\\)\n
\n \\(548\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(549\\)\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.366025\n \n +\n \n 1.36603i\n
\n \\(550\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(551\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(552\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(553\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(554\\)\n \n −1.00000\n \n −\n \n 1.00000i\n \n −1.00000\n \n −\n \n 1.00000i\n
\n \\(555\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(556\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(557\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(558\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(559\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(560\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(561\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(562\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(563\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(564\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(565\\)\n \n 1.00000\n \n +\n \n 1.73205i\n \n 1.00000\n \n +\n \n 1.73205i\n
\n \\(566\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(567\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(568\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(569\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(570\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(571\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.965926\n \n −\n \n 0.258819i\n \n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \n \\(0.916667\\pi\\)\n
\n \\(572\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(573\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(574\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(575\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(576\\)\n \n 0.866025\n \n −\n \n 0.500000i\n \n 0.866025\n \n −\n \n 0.500000i\n
\n \\(577\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(578\\)\n \n 0.866025\n \n +\n \n 0.500000i\n \n 0.866025\n \n +\n \n 0.500000i\n
\n \\(579\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(580\\)\n \n\n \n\n \n 2.00000i\n \n\n \n\n \n 2.00000i\n
\n \\(581\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(582\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(583\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(584\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n
\n \\(585\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(586\\)\n \n −1.73205\n \n +\n \n 1.00000i\n \n −1.73205\n \n +\n \n 1.00000i\n
\n \\(587\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(588\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(589\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(590\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(591\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(592\\)\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.366025\n \n −\n \n 1.36603i\n
\n \\(593\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(594\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(595\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(596\\)\n \n −2.00000\n \n\n \n\n \n −2.00000\n \n\n \n\n
\n \\(597\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(598\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(599\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(600\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(601\\)\n \n −1.00000\n \n −\n \n 1.00000i\n \n −1.00000\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(602\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(603\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(604\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(605\\)\n \n −1.36603\n \n +\n \n 0.366025i\n \n −1.36603\n \n +\n \n 0.366025i\n
\n \\(606\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(607\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.965926\n \n −\n \n 0.258819i\n \n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \n \\(0.0833333\\pi\\)\n
\n \\(608\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(609\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(610\\)\n \n\n \n −\n \n 2.00000i\n \n\n \n −\n \n 2.00000i\n
\n \\(611\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(612\\)\n \n −0.866025\n \n −\n \n 0.500000i\n \n −0.866025\n \n −\n \n 0.500000i\n
\n \\(613\\)\n \n −1.00000\n \n +\n \n 1.73205i\n \n −1.00000\n \n +\n \n 1.73205i\n \n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(614\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(615\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(616\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(617\\)\n \n −1.00000\n \n +\n \n 1.00000i\n \n −1.00000\n \n +\n \n 1.00000i\n \n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(618\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(619\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.965926\n \n −\n \n 0.258819i\n \n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \n \\(0.916667\\pi\\)\n
\n \\(620\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(621\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(622\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(623\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(624\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(625\\)\n \n −0.500000\n \n −\n \n 0.866025i\n \n −0.500000\n \n −\n \n 0.866025i\n
\n \\(626\\)\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.366025\n \n −\n \n 1.36603i\n
\n \\(627\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(628\\)\n \n −1.00000\n \n −\n \n 1.73205i\n \n −1.00000\n \n −\n \n 1.73205i\n
\n \\(629\\)\n \n −1.00000\n \n +\n \n 1.00000i\n \n −1.00000\n \n +\n \n 1.00000i\n
\n \\(630\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(631\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(632\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(633\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(634\\)\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.366025\n \n +\n \n 1.36603i\n
\n \\(635\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(636\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(637\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(638\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(639\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(640\\)\n \n −1.36603\n \n +\n \n 0.366025i\n \n −1.36603\n \n +\n \n 0.366025i\n
\n \\(641\\)\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n \\(642\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(643\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.707107\n \n −\n \n 0.707107i\n \n \\(-0.250000\\pi\\)\n
\n −0.707107\n \n +\n \n 0.707107i\n \n \\(0.750000\\pi\\)\n
\n \\(644\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(645\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(646\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(647\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(648\\)\n \n 0.866025\n \n +\n \n 0.500000i\n \n 0.866025\n \n +\n \n 0.500000i\n
\n \\(649\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(650\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(651\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(652\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(653\\)\n \n 0.366025\n \n −\n \n 1.36603i\n \n 0.366025\n \n −\n \n 1.36603i\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n \\(654\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(655\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(656\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n
\n \\(657\\)\n \n 1.00000\n \n +\n \n 1.00000i\n \n 1.00000\n \n +\n \n 1.00000i\n
\n \\(658\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(659\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(660\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(661\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(662\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(663\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(664\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(665\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(666\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n
\n \\(667\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(668\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(669\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(670\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(671\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(672\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(673\\)\n \n −1.00000\n \n −\n \n 1.00000i\n \n −1.00000\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(674\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n
\n \\(675\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(676\\)\n \n −0.500000\n \n +\n \n 0.866025i\n \n −0.500000\n \n +\n \n 0.866025i\n
\n \\(677\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(678\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(679\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(680\\)\n \n 1.00000\n \n +\n \n 1.00000i\n \n 1.00000\n \n +\n \n 1.00000i\n
\n \\(681\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(682\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(683\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.258819\n \n −\n \n 0.965926i\n \n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \n \\(0.416667\\pi\\)\n
\n \\(684\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(685\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(686\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(687\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(688\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(689\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(690\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(691\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.258819\n \n −\n \n 0.965926i\n \n \\(-0.416667\\pi\\)\n
\n −0.258819\n \n +\n \n 0.965926i\n \n \\(0.583333\\pi\\)\n
\n \\(692\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n
\n \\(693\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(694\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(695\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(696\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(697\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n
\n \\(698\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(699\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(700\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(701\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(702\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(703\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(704\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(705\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(706\\)\n \n\n \n −\n \n 2.00000i\n \n\n \n −\n \n 2.00000i\n
\n \\(707\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(708\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(709\\)\n \n −1.36603\n \n −\n \n 0.366025i\n \n −1.36603\n \n −\n \n 0.366025i\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(710\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(711\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(712\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(713\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(714\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(715\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(716\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(717\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(718\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(719\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.965926\n \n −\n \n 0.258819i\n \n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \n \\(0.0833333\\pi\\)\n
\n \\(720\\)\n \n −1.00000\n \n −\n \n 1.00000i\n \n −1.00000\n \n −\n \n 1.00000i\n
\n \\(721\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(722\\)\n \n\n \n\n \n 1.00000i\n \n\n \n\n \n 1.00000i\n
\n \\(723\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(724\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n
\n \\(725\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n
\n \\(726\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(727\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(728\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(729\\)\n \n\n \n\n \n 1.00000i\n \n\n \n\n \n 1.00000i\n
\n \\(730\\)\n \n −1.00000\n \n −\n \n 1.73205i\n \n −1.00000\n \n −\n \n 1.73205i\n
\n \\(731\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(732\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(733\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(734\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(735\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(736\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(737\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(738\\)\n \n −1.36603\n \n +\n \n 0.366025i\n \n −1.36603\n \n +\n \n 0.366025i\n
\n \\(739\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(740\\)\n \n −1.73205\n \n +\n \n 1.00000i\n \n −1.73205\n \n +\n \n 1.00000i\n
\n \\(741\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(742\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(743\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.707107\n \n −\n \n 0.707107i\n \n \\(-0.250000\\pi\\)\n
\n −0.707107\n \n +\n \n 0.707107i\n \n \\(0.750000\\pi\\)\n
\n \\(744\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(745\\)\n \n 0.732051\n \n +\n \n 2.73205i\n \n 0.732051\n \n +\n \n 2.73205i\n
\n \\(746\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(747\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(748\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(749\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(750\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(751\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.965926\n \n −\n \n 0.258819i\n \n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \n \\(0.0833333\\pi\\)\n
\n \\(752\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(753\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(754\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(755\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(756\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(757\\)\n \n\n \n\n \n 2.00000i\n \n\n \n\n \n 2.00000i\n \n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(758\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(759\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(760\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(761\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(762\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(763\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(764\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(765\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n
\n \\(766\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(767\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(768\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(769\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(770\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(771\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(772\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n
\n \\(773\\)\n \n −1.73205\n \n −\n \n 1.00000i\n \n −1.73205\n \n −\n \n 1.00000i\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n \\(774\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(775\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(776\\)\n \n 1.00000\n \n +\n \n 1.00000i\n \n 1.00000\n \n +\n \n 1.00000i\n
\n \\(777\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(778\\)\n \n 2.00000\n \n\n \n\n \n 2.00000\n \n\n \n\n
\n \\(779\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(780\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(781\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(782\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(783\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(784\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(785\\)\n \n −2.00000\n \n +\n \n 2.00000i\n \n −2.00000\n \n +\n \n 2.00000i\n
\n \\(786\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(787\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.258819\n \n −\n \n 0.965926i\n \n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \n \\(0.416667\\pi\\)\n
\n \\(788\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n
\n \\(789\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(790\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(791\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(792\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(793\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(794\\)\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.366025\n \n +\n \n 1.36603i\n
\n \\(795\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(796\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(797\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(798\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(799\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(800\\)\n \n 0.500000\n \n +\n \n 0.866025i\n \n 0.500000\n \n +\n \n 0.866025i\n
\n \\(801\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(802\\)\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.366025\n \n +\n \n 1.36603i\n
\n \\(803\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(804\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(805\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(806\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(807\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(808\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(809\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(810\\)\n \n 0.366025\n \n −\n \n 1.36603i\n \n 0.366025\n \n −\n \n 1.36603i\n
\n \\(811\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.707107\n \n −\n \n 0.707107i\n \n \\(-0.250000\\pi\\)\n
\n −0.707107\n \n +\n \n 0.707107i\n \n \\(0.750000\\pi\\)\n
\n \\(812\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(813\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(814\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(815\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(816\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(817\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(818\\)\n \n\n \n −\n \n 2.00000i\n \n\n \n −\n \n 2.00000i\n
\n \\(819\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(820\\)\n \n 2.00000\n \n\n \n\n \n 2.00000\n \n\n \n\n
\n \\(821\\)\n \n −1.36603\n \n −\n \n 0.366025i\n \n −1.36603\n \n −\n \n 0.366025i\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(822\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(823\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.965926\n \n −\n \n 0.258819i\n \n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \n \\(0.916667\\pi\\)\n
\n \\(824\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(825\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(826\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(827\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.707107\n \n −\n \n 0.707107i\n \n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \n \\(0.250000\\pi\\)\n
\n \\(828\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(829\\)\n \n 1.00000\n \n −\n \n 1.73205i\n \n 1.00000\n \n −\n \n 1.73205i\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n \\(830\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(831\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(832\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(833\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(834\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(835\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(836\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(837\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(838\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(839\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.707107\n \n −\n \n 0.707107i\n \n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \n \\(0.250000\\pi\\)\n
\n \\(840\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(841\\)\n \n\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n
\n \\(842\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(843\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(844\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(845\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n
\n \\(846\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(847\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(848\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(849\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(850\\)\n \n 0.500000\n \n −\n \n 0.866025i\n \n 0.500000\n \n −\n \n 0.866025i\n
\n \\(851\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(852\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(853\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n \\(854\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(855\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(856\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(857\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(858\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(859\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(860\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(861\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(862\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(863\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(864\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(865\\)\n \n −1.73205\n \n −\n \n 1.00000i\n \n −1.73205\n \n −\n \n 1.00000i\n
\n \\(866\\)\n \n −1.00000\n \n −\n \n 1.73205i\n \n −1.00000\n \n −\n \n 1.73205i\n
\n \\(867\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(868\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(869\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(870\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(871\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(872\\)\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.366025\n \n +\n \n 1.36603i\n
\n \\(873\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n
\n \\(874\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(875\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(876\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(877\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n \n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(878\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(879\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(880\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(881\\)\n \n −1.00000\n \n +\n \n 1.00000i\n \n −1.00000\n \n +\n \n 1.00000i\n \n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(882\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(883\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(884\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(885\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(886\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(887\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.965926\n \n −\n \n 0.258819i\n \n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \n \\(0.0833333\\pi\\)\n
\n \\(888\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(889\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(890\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(891\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(892\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(893\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(894\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(895\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(896\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(897\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(898\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n
\n \\(899\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(900\\)\n \n −0.500000\n \n +\n \n 0.866025i\n \n −0.500000\n \n +\n \n 0.866025i\n
\n \\(901\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(902\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(903\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(904\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n
\n \\(905\\)\n \n −1.00000\n \n −\n \n 1.73205i\n \n −1.00000\n \n −\n \n 1.73205i\n
\n \\(906\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(907\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.965926\n \n −\n \n 0.258819i\n \n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \n \\(0.916667\\pi\\)\n
\n \\(908\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(909\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(910\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(911\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.707107\n \n −\n \n 0.707107i\n \n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \n \\(0.250000\\pi\\)\n
\n \\(912\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(913\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(914\\)\n \n 1.00000\n \n −\n \n 1.73205i\n \n 1.00000\n \n −\n \n 1.73205i\n
\n \\(915\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(916\\)\n \n\n \n\n \n 2.00000i\n \n\n \n\n \n 2.00000i\n
\n \\(917\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(918\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(919\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(920\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(921\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(922\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(923\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(924\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(925\\)\n \n 1.00000\n \n +\n \n 1.00000i\n \n 1.00000\n \n +\n \n 1.00000i\n
\n \\(926\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(927\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(928\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n
\n \\(929\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n \n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(930\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(931\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(932\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n
\n \\(933\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(934\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(935\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(936\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(937\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(938\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(939\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(940\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(941\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(942\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(943\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(944\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(945\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(946\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(947\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.965926\n \n −\n \n 0.258819i\n \n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \n \\(0.0833333\\pi\\)\n
\n \\(948\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(949\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(950\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(951\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(952\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(953\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(954\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(955\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(956\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(957\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(958\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(959\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(960\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(961\\)\n \n −0.866025\n \n +\n \n 0.500000i\n \n −0.866025\n \n +\n \n 0.500000i\n
\n \\(962\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(963\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(964\\)\n \n −1.36603\n \n −\n \n 0.366025i\n \n −1.36603\n \n −\n \n 0.366025i\n
\n \\(965\\)\n \n 2.00000\n \n\n \n\n \n 2.00000\n \n\n \n\n
\n \\(966\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(967\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(968\\)\n \n 0.500000\n \n +\n \n 0.866025i\n \n 0.500000\n \n +\n \n 0.866025i\n
\n \\(969\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(970\\)\n \n 1.00000\n \n −\n \n 1.73205i\n \n 1.00000\n \n −\n \n 1.73205i\n
\n \\(971\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(972\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(973\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(974\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(975\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(976\\)\n \n −1.36603\n \n +\n \n 0.366025i\n \n −1.36603\n \n +\n \n 0.366025i\n
\n \\(977\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(978\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(979\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(980\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(981\\)\n \n −1.00000\n \n +\n \n 1.00000i\n \n −1.00000\n \n +\n \n 1.00000i\n
\n \\(982\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(983\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.258819\n \n −\n \n 0.965926i\n \n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \n \\(0.416667\\pi\\)\n
\n \\(984\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(985\\)\n \n −1.00000\n \n −\n \n 1.73205i\n \n −1.00000\n \n −\n \n 1.73205i\n
\n \\(986\\)\n \n −1.00000\n \n −\n \n 1.00000i\n \n −1.00000\n \n −\n \n 1.00000i\n
\n \\(987\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(988\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(989\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(990\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(991\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.258819\n \n −\n \n 0.965926i\n \n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \n \\(0.416667\\pi\\)\n
\n \\(992\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(993\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(994\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(995\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(996\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(997\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(998\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(999\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n
\n
\n \n\n \n (See \\(a_n\\) instead)\n \n\n \n (See \\(a_n\\) instead)\n \n\n \n (See \\(a_n\\) instead)\n \n \n\n \n (See only \\(a_p\\))\n \n\n \n (See only \\(a_p\\))\n \n\n \n (See only \\(a_p\\))\n \n
\n\n\n\n\n\n\n\n \n \n \n \n \n \n \n\n\n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n
       By twisting character
CharParityOrdTypeTwistMinDim
1.1even1trivial3332.1.bc.b.2027.14
4.3odd2CM3332.1.bc.b.2027.14
7.2even3inner3332.1.bc.b.667.14
7.3odd668.1.f.a.55.1yes2
7.4even33332.1.m.b.2843.12
7.5odd63332.1.bc.c.667.14
7.6odd23332.1.bc.c.2027.14
17.13even4inner3332.1.bc.b.2223.14
21.17even6612.1.l.a.55.12
28.3even668.1.f.a.55.1yes2
28.11odd63332.1.m.b.2843.12
28.19even63332.1.bc.c.667.14
28.23odd6inner3332.1.bc.b.667.14
28.27even23332.1.bc.c.2027.14
35.3even121700.1.n.a.599.12
35.17even121700.1.n.b.599.12
35.24odd61700.1.p.a.1551.12
56.3even61088.1.p.a.191.12
56.45odd61088.1.p.a.191.12
68.47odd4inner3332.1.bc.b.2223.14
84.59odd6612.1.l.a.55.12
119.3even481156.1.g.b.155.18
119.10even481156.1.g.b.179.18
119.13odd43332.1.bc.c.2223.14
119.24even481156.1.g.b.179.28
119.30even12inner3332.1.bc.b.863.14
119.31even481156.1.g.b.155.28
119.38odd121156.1.f.b.251.12
119.45even481156.1.g.b.399.18
119.47odd123332.1.bc.c.863.14
119.59odd241156.1.c.b.579.12
119.66odd241156.1.d.a.1155.22
119.73even481156.1.g.b.423.28
119.80even481156.1.g.b.423.18
119.81even123332.1.m.b.3039.12
119.87odd241156.1.d.a.1155.12
119.94odd241156.1.c.b.579.22
119.101odd61156.1.f.b.327.12
119.108even481156.1.g.b.399.28
119.115odd1268.1.f.a.47.1&check;2
140.3odd121700.1.n.a.599.12
140.59even61700.1.p.a.1551.12
140.87odd121700.1.n.b.599.12
357.353even12612.1.l.a.523.12
476.3odd481156.1.g.b.155.18
476.31odd481156.1.g.b.155.28
476.47even123332.1.bc.c.863.14
476.59even241156.1.c.b.579.12
476.87even241156.1.d.a.1155.12
476.115even1268.1.f.a.47.1&check;2
476.143odd481156.1.g.b.179.28
476.199odd481156.1.g.b.423.18
476.227odd481156.1.g.b.399.28
476.251even43332.1.bc.c.2223.14
476.283odd481156.1.g.b.399.18
476.311odd481156.1.g.b.423.28
476.319odd123332.1.m.b.3039.12
476.339even61156.1.f.b.327.12
476.367odd481156.1.g.b.179.18
476.387odd12inner3332.1.bc.b.863.14
476.395even121156.1.f.b.251.12
476.423even241156.1.d.a.1155.22
476.451even241156.1.c.b.579.22
595.234odd121700.1.p.a.251.12
595.353even121700.1.n.b.999.12
595.472even121700.1.n.a.999.12
952.115even121088.1.p.a.319.12
952.829odd121088.1.p.a.319.12
1428.1067odd12612.1.l.a.523.12
2380.1067odd121700.1.n.a.999.12
2380.1543odd121700.1.n.b.999.12
2380.2019even121700.1.p.a.251.12
\n
    
\n\n\n\n\n \n \n \n \n \n \n \n\n\n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n
        By twisted newform
TwistMinDimCharParityOrdType
68.1.f.a.47.1&check;2119.115odd12
68.1.f.a.47.1&check;2476.115even12
68.1.f.a.55.1yes27.3odd6
68.1.f.a.55.1yes228.3even6
612.1.l.a.55.1221.17even6
612.1.l.a.55.1284.59odd6
612.1.l.a.523.12357.353even12
612.1.l.a.523.121428.1067odd12
1088.1.p.a.191.1256.3even6
1088.1.p.a.191.1256.45odd6
1088.1.p.a.319.12952.115even12
1088.1.p.a.319.12952.829odd12
1156.1.c.b.579.12119.59odd24
1156.1.c.b.579.12476.59even24
1156.1.c.b.579.22119.94odd24
1156.1.c.b.579.22476.451even24
1156.1.d.a.1155.12119.87odd24
1156.1.d.a.1155.12476.87even24
1156.1.d.a.1155.22119.66odd24
1156.1.d.a.1155.22476.423even24
1156.1.f.b.251.12119.38odd12
1156.1.f.b.251.12476.395even12
1156.1.f.b.327.12119.101odd6
1156.1.f.b.327.12476.339even6
1156.1.g.b.155.18119.3even48
1156.1.g.b.155.18476.3odd48
1156.1.g.b.155.28119.31even48
1156.1.g.b.155.28476.31odd48
1156.1.g.b.179.18119.10even48
1156.1.g.b.179.18476.367odd48
1156.1.g.b.179.28119.24even48
1156.1.g.b.179.28476.143odd48
1156.1.g.b.399.18119.45even48
1156.1.g.b.399.18476.283odd48
1156.1.g.b.399.28119.108even48
1156.1.g.b.399.28476.227odd48
1156.1.g.b.423.18119.80even48
1156.1.g.b.423.18476.199odd48
1156.1.g.b.423.28119.73even48
1156.1.g.b.423.28476.311odd48
1700.1.n.a.599.1235.3even12
1700.1.n.a.599.12140.3odd12
1700.1.n.a.999.12595.472even12
1700.1.n.a.999.122380.1067odd12
1700.1.n.b.599.1235.17even12
1700.1.n.b.599.12140.87odd12
1700.1.n.b.999.12595.353even12
1700.1.n.b.999.122380.1543odd12
1700.1.p.a.251.12595.234odd12
1700.1.p.a.251.122380.2019even12
1700.1.p.a.1551.1235.24odd6
1700.1.p.a.1551.12140.59even6
3332.1.m.b.2843.127.4even3
3332.1.m.b.2843.1228.11odd6
3332.1.m.b.3039.12119.81even12
3332.1.m.b.3039.12476.319odd12
3332.1.bc.b.667.147.2even3inner
3332.1.bc.b.667.1428.23odd6inner
3332.1.bc.b.863.14119.30even12inner
3332.1.bc.b.863.14476.387odd12inner
3332.1.bc.b.2027.141.1even1trivial
3332.1.bc.b.2027.144.3odd2CM
3332.1.bc.b.2223.1417.13even4inner
3332.1.bc.b.2223.1468.47odd4inner
3332.1.bc.c.667.147.5odd6
3332.1.bc.c.667.1428.19even6
3332.1.bc.c.863.14119.47odd12
3332.1.bc.c.863.14476.47even12
3332.1.bc.c.2027.147.6odd2
3332.1.bc.c.2027.1428.27even2
3332.1.bc.c.2223.14119.13odd4
3332.1.bc.c.2223.14476.251even4
\n
\n\n\n\n

\n
\n", "content_list": [[{"type": "paragraph", "raw_content": "
\n Show commands:\n Magma\n / PariGP\n / SageMath
", "content": [{"c": "Show commands: Magma/ PariGP/ SageMath", "t": "text"}]}, {"type": "code", "raw_content": "
[N,k,chi] = [3332,1,Mod(667,3332)]
 
mf = mfinit([N,k,chi],0)
 
lf = mfeigenbasis(mf)
 
\n", "inline": false, "content": {"code_content": "[N,k,chi] = [3332,1,Mod(667,3332)]\n\nmf = mfinit([N,k,chi],0)\n\nlf = mfeigenbasis(mf)", "by": "classname"}}, {"type": "code", "raw_content": "
from sage.modular.dirichlet import DirichletCharacter
 
H = DirichletGroup(3332, base_ring=CyclotomicField(12))
 
chi = DirichletCharacter(H, H._module([6, 4, 9]))
 
N = Newforms(chi, 1, names=\"a\")
 
\n", "inline": false, "content": {"code_content": "from sage.modular.dirichlet import DirichletCharacter\n\nH = DirichletGroup(3332, base_ring=CyclotomicField(12))\n\nchi = DirichletCharacter(H, H._module([6, 4, 9]))\n\nN = Newforms(chi, 1, names=\"a\")", "by": "classname"}}, {"type": "code", "raw_content": "
//Please install CHIMP (https://github.com/edgarcosta/CHIMP) if you want to run this code
 
chi := DirichletCharacter(\"3332.667\");
 
S:= CuspForms(chi, 1);
 
N := Newforms(S);
 
\n\n\n", "inline": false, "content": {"code_content": "//Please install CHIMP (https://github.com/edgarcosta/CHIMP) if you want to run this code\n\nchi := DirichletCharacter(\"3332.667\");\n\nS:= CuspForms(chi, 1);\n\nN := Newforms(S);", "by": "classname"}}, {"type": "simple_table", "raw_content": "
Level: \\( N \\) \\(=\\)\\( 3332 = 2^{2} \\cdot 7^{2} \\cdot 17 \\)
Weight: \\( k \\) \\(=\\)\\( 1 \\)
Character orbit: \\([\\chi]\\) \\(=\\)3332.bc (of order \\(12\\), degree \\(4\\), not minimal)
", "content": {"html": "
Level :$N$$=$$3332 = 2^{2} \\cdot 7^{2} \\cdot 17$
Weight :$k$$=$$1$
Character orbit :$[\\chi]$$=$3332.bc (oforder12, degree4, not minimal )
", "is_complex": false, "table_nest_level": "1"}}, {"type": "title", "raw_content": "

Newform invariants

", "content": {"title_content": "Newform invariants", "level": "2"}}, {"type": "code", "raw_content": "
sage: f = N[0] # Warning: the index may be different
 
\n", "inline": false, "content": {"code_content": "sage: f = N[0] # Warning: the index may be different", "by": "classname"}}, {"type": "code", "raw_content": "
gp: f = lf[1] \\\\ Warning: the index may be different
 
\n\n\n", "inline": false, "content": {"code_content": "gp: f = lf[1] \\\\ Warning: the index may be different", "by": "classname"}}, {"type": "complex_table", "raw_content": "
Self dual: no
Analytic conductor: \\(1.66288462209\\)
Analytic rank: \\(0\\)
Dimension: \\(4\\)
Coefficient field: \\(\\Q(\\zeta_{12})\\)
", "content": {"html": "
Self dual :no
Analytic conductor :$1.66288462209$
Analytic rank :$0$
Dimension :$4$
Coefficient field :$\\Q(\\zeta_{12})$
", "is_complex": true, "table_nest_level": "1"}}, {"type": "code", "raw_content": "
gp: f.mod \\\\ as an extension of the character field
 
\n\n ", "inline": false, "content": {"code_content": "gp: f.mod \\\\ as an extension of the character field", "by": "classname"}}, {"type": "complex_table", "raw_content": "
Defining polynomial: \\( x^{4} - x^{2} + 1 \\)\"Copy\"Toggle
Coefficient ring: \\(\\Z[a_1, a_2]\\)
Coefficient ring index: \\( 1 \\)
Twist minimal: no (minimal twist has level 68)
Projective image:\\(D_{4}\\)
Projective field:Galois closure of 4.2.19652.1
Artin image:$C_4\\wr C_2\\times C_6$
Artin field:Galois closure of \\(\\mathbb{Q}[x]/(x^{48} - \\cdots)\\)
", "content": {"html": "
Defining polynomial :$x^{4} - x^{2} + 1$
Coefficient ring :$\\Z[a_1, a_2]$
Coefficient ring index :$1$
Twist minimal :no (minimal twist has level 68)
Projective image :$D_{4}$
Projective field :Galois closure of 4.2.19652.1
Artin image :$C_4\\wr C_2\\times C_6$
Artin field :Galois closure of $\\mathbb{Q}[x]/(x^{48} - \\cdots)$
", "is_complex": true, "table_nest_level": "1"}}, {"type": "title", "raw_content": "

Embedding invariants

", "content": {"title_content": "Embedding invariants", "level": "2"}}, {"type": "simple_table", "raw_content": "
Embedding label 2027.1
Root\\(0.866025 - 0.500000i\\) of defining polynomial
Character\\(\\chi\\)\\(=\\)3332.2027
Dual form3332.1.bc.b.863.1
", "content": {"html": "
Embedding label2027.1
Root$0.866025 - 0.500000i$ of defining polynomial
Character$\\chi$$=$3332.2027
Dual form3332.1.bc.b.863.1
", "is_complex": false, "table_nest_level": "1"}}, {"type": "code", "raw_content": "
sage: f.q_expansion() # note that sage often uses an isomorphic number field
 
\n", "inline": false, "content": {"code_content": "sage: f.q_expansion() # note that sage often uses an isomorphic number field", "by": "classname"}}, {"type": "code", "raw_content": "
gp: mfcoefs(f, 20)
 
\n\n ", "inline": false, "content": {"code_content": "gp: mfcoefs(f, 20)", "by": "classname"}}, {"type": "simple_table", "raw_content": "
\\(f(q)\\)\\(=\\)\\(q+(-0.866025 + 0.500000i) q^{2} +(0.500000 - 0.866025i) q^{4} +(-1.36603 - 0.366025i) q^{5} +1.00000i q^{8} +(-0.866025 + 0.500000i) q^{9} +(1.36603 - 0.366025i) q^{10} +(-0.500000 - 0.866025i) q^{16} +(-0.500000 + 0.866025i) q^{17} +(0.500000 - 0.866025i) q^{18} +(-1.00000 + 1.00000i) q^{20} +(0.866025 + 0.500000i) q^{25} +(1.00000 - 1.00000i) q^{29} +(0.866025 + 0.500000i) q^{32} -1.00000i q^{34} +1.00000i q^{36} +(1.36603 + 0.366025i) q^{37} +(0.366025 - 1.36603i) q^{40} +(-1.00000 - 1.00000i) q^{41} +(1.36603 - 0.366025i) q^{45} -1.00000 q^{50} +(-0.366025 + 1.36603i) q^{58} +(0.366025 - 1.36603i) q^{61} -1.00000 q^{64} +(0.500000 + 0.866025i) q^{68} +(-0.500000 - 0.866025i) q^{72} +(-0.366025 - 1.36603i) q^{73} +(-1.36603 + 0.366025i) q^{74} +(0.366025 + 1.36603i) q^{80} +(0.500000 - 0.866025i) q^{81} +(1.36603 + 0.366025i) q^{82} +(1.00000 - 1.00000i) q^{85} +(-1.00000 + 1.00000i) q^{90} +(1.00000 - 1.00000i) q^{97} +O(q^{100})\\)
\\(\\operatorname{Tr}(f)(q)\\)\\(=\\)\\( 4 q + 2 q^{4} - 2 q^{5} + 2 q^{10} - 2 q^{16} - 2 q^{17} + 2 q^{18} - 4 q^{20} + 4 q^{29} + 2 q^{37} - 2 q^{40} - 4 q^{41} + 2 q^{45} - 4 q^{50} + 2 q^{58} - 2 q^{61} - 4 q^{64} + 2 q^{68} - 2 q^{72} + 2 q^{73}+ \\cdots + 4 q^{97}+O(q^{100}) \\)\"Copy\"Toggle
", "content": {"html": "
$f(q)$$=$$q+(-0.866025 + 0.500000i) q^{2} +(0.500000 - 0.866025i) q^{4} +(-1.36603 - 0.366025i) q^{5} +1.00000i q^{8} +(-0.866025 + 0.500000i) q^{9} +(1.36603 - 0.366025i) q^{10} +(-0.500000 - 0.866025i) q^{16} +(-0.500000 + 0.866025i) q^{17} +(0.500000 - 0.866025i) q^{18} +(-1.00000 + 1.00000i) q^{20} +(0.866025 + 0.500000i) q^{25} +(1.00000 - 1.00000i) q^{29} +(0.866025 + 0.500000i) q^{32} -1.00000i q^{34} +1.00000i q^{36} +(1.36603 + 0.366025i) q^{37} +(0.366025 - 1.36603i) q^{40} +(-1.00000 - 1.00000i) q^{41} +(1.36603 - 0.366025i) q^{45} -1.00000 q^{50} +(-0.366025 + 1.36603i) q^{58} +(0.366025 - 1.36603i) q^{61} -1.00000 q^{64} +(0.500000 + 0.866025i) q^{68} +(-0.500000 - 0.866025i) q^{72} +(-0.366025 - 1.36603i) q^{73} +(-1.36603 + 0.366025i) q^{74} +(0.366025 + 1.36603i) q^{80} +(0.500000 - 0.866025i) q^{81} +(1.36603 + 0.366025i) q^{82} +(1.00000 - 1.00000i) q^{85} +(-1.00000 + 1.00000i) q^{90} +(1.00000 - 1.00000i) q^{97} +O(q^{100})$
$\\operatorname{Tr}(f)(q)$$=$$4 q + 2 q^{4} - 2 q^{5} + 2 q^{10} - 2 q^{16} - 2 q^{17} + 2 q^{18} - 4 q^{20} + 4 q^{29} + 2 q^{37} - 2 q^{40} - 4 q^{41} + 2 q^{45} - 4 q^{50} + 2 q^{58} - 2 q^{61} - 4 q^{64} + 2 q^{68} - 2 q^{72} + 2 q^{73}+ \\cdots + 4 q^{97}+O(q^{100})$
", "is_complex": false, "table_nest_level": "1"}}, {"type": "title", "raw_content": "

Character values

", "content": {"title_content": "Character values", "level": "2"}}, {"type": "paragraph", "raw_content": "

We give the values of \\chi on generators for \\left(\\mathbb{Z}/3332\\mathbb{Z}\\right)^\\times.

", "content": [{"c": "We give the values of", "t": "text"}, {"c": "\\chi", "t": "equation-inline"}, {"c": "on generators for", "t": "text"}, {"c": "\\left(\\mathbb{Z}/3332\\mathbb{Z}\\right)^\\times", "t": "equation-inline"}, {"c": ".", "t": "text"}]}, {"type": "simple_table", "raw_content": "
\\(n\\)\\(785\\)\\(885\\)\\(1667\\)
\\(\\chi(n)\\)\\(e\\left(\\frac{3}{4}\\right)\\)\\(e\\left(\\frac{2}{3}\\right)\\)\\(-1\\)
", "content": {"html": "
$n$$785$$885$$1667$
$\\chi(n)$$e\\left(\\frac{3}{4}\\right)$$e\\left(\\frac{2}{3}\\right)$$-1$
", "is_complex": false, "table_nest_level": "1"}}, {"type": "title", "raw_content": "

Coefficient data

", "content": {"title_content": "Coefficient data", "level": "2"}}, {"type": "paragraph", "raw_content": "

For each n we display the coefficients of the q-expansion a_n, the\nSatake parameters\\alpha_p,\nand the Satake angles \\theta_p = \\textrm{Arg}(\\alpha_p).

", "content": [{"c": "For each", "t": "text"}, {"c": "n", "t": "equation-inline"}, {"c": "we display the coefficients of the", "t": "text"}, {"c": "q", "t": "equation-inline"}, {"c": "-expansion", "t": "text"}, {"c": "a_n", "t": "equation-inline"}, {"c": ", the Satake parameters", "t": "text"}, {"c": "\\alpha_p", "t": "equation-inline"}, {"c": ", and the Satake angles", "t": "text"}, {"c": "\\theta_p = \\textrm{Arg}(\\alpha_p)", "t": "equation-inline"}, {"c": ".", "t": "text"}]}, {"type": "paragraph", "raw_content": "
\n (See a_n instead)\n \n (See a_n instead)\n \n (See a_n instead)\n \n (See only a_p)\n \n (See only a_p)\n \n (See only a_p)\n
", "content": [{"c": "(See", "t": "text"}, {"c": "a_n", "t": "equation-inline"}, {"c": "instead)(See", "t": "text"}, {"c": "a_n", "t": "equation-inline"}, {"c": "instead)(See", "t": "text"}, {"c": "a_n", "t": "equation-inline"}, {"c": "instead)(See only", "t": "text"}, {"c": "a_p", "t": "equation-inline"}, {"c": ")(See only", "t": "text"}, {"c": "a_p", "t": "equation-inline"}, {"c": ")(See only", "t": "text"}, {"c": "a_p", "t": "equation-inline"}, {"c": ")", "t": "text"}]}, {"type": "complex_table", "raw_content": "
\n \\(n\\)\n \n \\(a_n\\)\n \n \\(a_n / n^{(k-1)/2}\\)\n \n \\( \\alpha_n \\)\n \n \\( \\theta_n \\)\n
\n \\(p\\)\n \n \\(a_p\\)\n \n \\(a_p / p^{(k-1)/2}\\)\n \n \\( \\alpha_p\\)\n \n \\( \\theta_p \\)\n
\n \\(2\\)\n \n −0.866025\n \n +\n \n 0.500000i\n −0.866025\n \n +\n \n 0.500000i
\n \\(3\\)\n \n 0\n \n 0\n \n −0.258819\n \n −\n \n 0.965926i\n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \\(0.416667\\pi\\)\n
\n \\(4\\)\n \n 0.500000\n \n −\n \n 0.866025i\n 0.500000\n \n −\n \n 0.866025i
\n \\(5\\)\n \n −1.36603\n \n −\n \n 0.366025i\n −1.36603\n \n −\n \n 0.366025i\n −0.500000\n \n −\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(6\\)\n \n 0\n \n 0\n
\n \\(7\\)\n \n 0\n \n 0\n
\n \\(8\\)\n \n 1.00000i\n 1.00000i
\n \\(9\\)\n \n −0.866025\n \n +\n \n 0.500000i\n −0.866025\n \n +\n \n 0.500000i
\n \\(10\\)\n \n 1.36603\n \n −\n \n 0.366025i\n 1.36603\n \n −\n \n 0.366025i
\n \\(11\\)\n \n 0\n \n 0\n \n 0.965926\n \n −\n \n 0.258819i\n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \\(0.916667\\pi\\)\n
\n \\(12\\)\n \n 0\n \n 0\n
\n \\(13\\)\n \n 0\n \n 0\n \n −\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(14\\)\n \n 0\n \n 0\n
\n \\(15\\)\n \n 0\n \n 0\n
\n \\(16\\)\n \n −0.500000\n \n −\n \n 0.866025i\n −0.500000\n \n −\n \n 0.866025i
\n \\(17\\)\n \n −0.500000\n \n +\n \n 0.866025i\n −0.500000\n \n +\n \n 0.866025i
\n \\(18\\)\n \n 0.500000\n \n −\n \n 0.866025i\n 0.500000\n \n −\n \n 0.866025i
\n \\(19\\)\n \n 0\n \n 0\n \n 0.866025\n \n −\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(20\\)\n \n −1.00000\n \n +\n \n 1.00000i\n −1.00000\n \n +\n \n 1.00000i
\n \\(21\\)\n \n 0\n \n 0\n
\n \\(22\\)\n \n 0\n \n 0\n
\n \\(23\\)\n \n 0\n \n 0\n \n 0.258819\n \n −\n \n 0.965926i\n \\(-0.416667\\pi\\)\n
\n −0.258819\n \n +\n \n 0.965926i\n \\(0.583333\\pi\\)\n
\n \\(24\\)\n \n 0\n \n 0\n
\n \\(25\\)\n \n 0.866025\n \n +\n \n 0.500000i\n 0.866025\n \n +\n \n 0.500000i
\n \\(26\\)\n \n 0\n \n 0\n
\n \\(27\\)\n \n 0\n \n 0\n
\n \\(28\\)\n \n 0\n \n 0\n
\n \\(29\\)\n \n 1.00000\n \n −\n \n 1.00000i\n 1.00000\n \n −\n \n 1.00000i\n −\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000\n \n \\(0\\)\n
\n \\(30\\)\n \n 0\n \n 0\n
\n \\(31\\)\n \n 0\n \n 0\n \n −0.258819\n \n −\n \n 0.965926i\n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \\(0.416667\\pi\\)\n
\n \\(32\\)\n \n 0.866025\n \n +\n \n 0.500000i\n 0.866025\n \n +\n \n 0.500000i
\n \\(33\\)\n \n 0\n \n 0\n
\n \\(34\\)\n \n −\n \n 1.00000i\n −\n \n 1.00000i
\n \\(35\\)\n \n 0\n \n 0\n
\n \\(36\\)\n \n 1.00000i\n 1.00000i
\n \\(37\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i\n 0.866025\n \n −\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(38\\)\n \n 0\n \n 0\n
\n \\(39\\)\n \n 0\n \n 0\n
\n \\(40\\)\n \n 0.366025\n \n −\n \n 1.36603i\n 0.366025\n \n −\n \n 1.36603i
\n \\(41\\)\n \n −1.00000\n \n −\n \n 1.00000i\n −1.00000\n \n −\n \n 1.00000i\n −\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n −1.00000\n \n \\(\\pi\\)\n
\n \\(42\\)\n \n 0\n \n 0\n
\n \\(43\\)\n \n 0\n \n 0\n \n −\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(44\\)\n \n 0\n \n 0\n
\n \\(45\\)\n \n 1.36603\n \n −\n \n 0.366025i\n 1.36603\n \n −\n \n 0.366025i
\n \\(46\\)\n \n 0\n \n 0\n
\n \\(47\\)\n \n 0\n \n 0\n \n −0.500000\n \n −\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(48\\)\n \n 0\n \n 0\n
\n \\(49\\)\n \n 0\n \n 0\n
\n \\(50\\)\n \n −1.00000\n \n −1.00000\n
\n \\(51\\)\n \n 0\n \n 0\n
\n \\(52\\)\n \n 0\n \n 0\n
\n \\(53\\)\n \n 0\n \n 0\n \n 0.500000\n \n −\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(54\\)\n \n 0\n \n 0\n
\n \\(55\\)\n \n 0\n \n 0\n
\n \\(56\\)\n \n 0\n \n 0\n
\n \\(57\\)\n \n 0\n \n 0\n
\n \\(58\\)\n \n −0.366025\n \n +\n \n 1.36603i\n −0.366025\n \n +\n \n 1.36603i
\n \\(59\\)\n \n 0\n \n 0\n \n −0.866025\n \n −\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(60\\)\n \n 0\n \n 0\n
\n \\(61\\)\n \n 0.366025\n \n −\n \n 1.36603i\n 0.366025\n \n −\n \n 1.36603i\n −0.500000\n \n −\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.866025\n \n −\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \\(62\\)\n \n 0\n \n 0\n
\n \\(63\\)\n \n 0\n \n 0\n
\n \\(64\\)\n \n −1.00000\n \n −1.00000\n
\n \\(65\\)\n \n 0\n \n 0\n
\n \\(66\\)\n \n 0\n \n 0\n
\n \\(67\\)\n \n 0\n \n 0\n \n 0.500000\n \n −\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(68\\)\n \n 0.500000\n \n +\n \n 0.866025i\n 0.500000\n \n +\n \n 0.866025i
\n \\(69\\)\n \n 0\n \n 0\n
\n \\(70\\)\n \n 0\n \n 0\n
\n \\(71\\)\n \n 0\n \n 0\n \n 0.707107\n \n −\n \n 0.707107i\n \\(-0.250000\\pi\\)\n
\n −0.707107\n \n +\n \n 0.707107i\n \\(0.750000\\pi\\)\n
\n \\(72\\)\n \n −0.500000\n \n −\n \n 0.866025i\n −0.500000\n \n −\n \n 0.866025i
\n \\(73\\)\n \n −0.366025\n \n −\n \n 1.36603i\n −0.366025\n \n −\n \n 1.36603i\n −0.866025\n \n −\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.500000\n \n −\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n \\(74\\)\n \n −1.36603\n \n +\n \n 0.366025i\n −1.36603\n \n +\n \n 0.366025i
\n \\(75\\)\n \n 0\n \n 0\n
\n \\(76\\)\n \n 0\n \n 0\n
\n \\(77\\)\n \n 0\n \n 0\n
\n \\(78\\)\n \n 0\n \n 0\n
\n \\(79\\)\n \n 0\n \n 0\n \n 0.258819\n \n −\n \n 0.965926i\n \\(-0.416667\\pi\\)\n
\n −0.258819\n \n +\n \n 0.965926i\n \\(0.583333\\pi\\)\n
\n \\(80\\)\n \n 0.366025\n \n +\n \n 1.36603i\n 0.366025\n \n +\n \n 1.36603i
\n \\(81\\)\n \n 0.500000\n \n −\n \n 0.866025i\n 0.500000\n \n −\n \n 0.866025i
\n \\(82\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i
\n \\(83\\)\n \n 0\n \n 0\n \n −\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(84\\)\n \n 0\n \n 0\n
\n \\(85\\)\n \n 1.00000\n \n −\n \n 1.00000i\n 1.00000\n \n −\n \n 1.00000i
\n \\(86\\)\n \n 0\n \n 0\n
\n \\(87\\)\n \n 0\n \n 0\n
\n \\(88\\)\n \n 0\n \n 0\n
\n \\(89\\)\n \n 0\n \n 0\n \n 0.866025\n \n −\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(90\\)\n \n −1.00000\n \n +\n \n 1.00000i\n −1.00000\n \n +\n \n 1.00000i
\n \\(91\\)\n \n 0\n \n 0\n
\n \\(92\\)\n \n 0\n \n 0\n
\n \\(93\\)\n \n 0\n \n 0\n
\n \\(94\\)\n \n 0\n \n 0\n
\n \\(95\\)\n \n 0\n \n 0\n
\n \\(96\\)\n \n 0\n \n 0\n
\n \\(97\\)\n \n 1.00000\n \n −\n \n 1.00000i\n 1.00000\n \n −\n \n 1.00000i\n −\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000\n \n \\(0\\)\n
\n \\(98\\)\n \n 0\n \n 0\n
\n \\(99\\)\n \n 0\n \n 0\n
\n \\(100\\)\n \n 0.866025\n \n −\n \n 0.500000i\n 0.866025\n \n −\n \n 0.500000i
\n \\(101\\)\n \n 0\n \n 0\n \n −0.866025\n \n −\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(102\\)\n \n 0\n \n 0\n
\n \\(103\\)\n \n 0\n \n 0\n \n −0.500000\n \n −\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(104\\)\n \n 0\n \n 0\n
\n \\(105\\)\n \n 0\n \n 0\n
\n \\(106\\)\n \n 0\n \n 0\n
\n \\(107\\)\n \n 0\n \n 0\n \n −0.965926\n \n −\n \n 0.258819i\n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \\(0.0833333\\pi\\)\n
\n \\(108\\)\n \n 0\n \n 0\n
\n \\(109\\)\n \n 1.36603\n \n −\n \n 0.366025i\n 1.36603\n \n −\n \n 0.366025i\n 0.500000\n \n −\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(110\\)\n \n 0\n \n 0\n
\n \\(111\\)\n \n 0\n \n 0\n
\n \\(112\\)\n \n 0\n \n 0\n
\n \\(113\\)\n \n −1.00000\n \n −\n \n 1.00000i\n −1.00000\n \n −\n \n 1.00000i\n −\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n −1.00000\n \n \\(\\pi\\)\n
\n \\(114\\)\n \n 0\n \n 0\n
\n \\(115\\)\n \n 0\n \n 0\n
\n \\(116\\)\n \n −0.366025\n \n −\n \n 1.36603i\n −0.366025\n \n −\n \n 1.36603i
\n \\(117\\)\n \n 0\n \n 0\n
\n \\(118\\)\n \n 0\n \n 0\n
\n \\(119\\)\n \n 0\n \n 0\n
\n \\(120\\)\n \n 0\n \n 0\n
\n \\(121\\)\n \n 0.866025\n \n −\n \n 0.500000i\n 0.866025\n \n −\n \n 0.500000i
\n \\(122\\)\n \n 0.366025\n \n +\n \n 1.36603i\n 0.366025\n \n +\n \n 1.36603i
\n \\(123\\)\n \n 0\n \n 0\n
\n \\(124\\)\n \n 0\n \n 0\n
\n \\(125\\)\n \n 0\n \n 0\n
\n \\(126\\)\n \n 0\n \n 0\n
\n \\(127\\)\n \n 0\n \n 0\n \n −\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(128\\)\n \n 0.866025\n \n −\n \n 0.500000i\n 0.866025\n \n −\n \n 0.500000i
\n \\(129\\)\n \n 0\n \n 0\n
\n \\(130\\)\n \n 0\n \n 0\n
\n \\(131\\)\n \n 0\n \n 0\n \n −0.965926\n \n −\n \n 0.258819i\n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \\(0.0833333\\pi\\)\n
\n \\(132\\)\n \n 0\n \n 0\n
\n \\(133\\)\n \n 0\n \n 0\n
\n \\(134\\)\n \n 0\n \n 0\n
\n \\(135\\)\n \n 0\n \n 0\n
\n \\(136\\)\n \n −0.866025\n \n −\n \n 0.500000i\n −0.866025\n \n −\n \n 0.500000i
\n \\(137\\)\n \n 0\n \n 0\n \n −0.866025\n \n −\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(138\\)\n \n 0\n \n 0\n
\n \\(139\\)\n \n 0\n \n 0\n \n 0.707107\n \n −\n \n 0.707107i\n \\(-0.250000\\pi\\)\n
\n −0.707107\n \n +\n \n 0.707107i\n \\(0.750000\\pi\\)\n
\n \\(140\\)\n \n 0\n \n 0\n
\n \\(141\\)\n \n 0\n \n 0\n
\n \\(142\\)\n \n 0\n \n 0\n
\n \\(143\\)\n \n 0\n \n 0\n
\n \\(144\\)\n \n 0.866025\n \n +\n \n 0.500000i\n 0.866025\n \n +\n \n 0.500000i
\n \\(145\\)\n \n −1.73205\n \n +\n \n 1.00000i\n −1.73205\n \n +\n \n 1.00000i
\n \\(146\\)\n \n 1.00000\n \n +\n \n 1.00000i\n 1.00000\n \n +\n \n 1.00000i
\n \\(147\\)\n \n 0\n \n 0\n
\n \\(148\\)\n \n 1.00000\n \n −\n \n 1.00000i\n 1.00000\n \n −\n \n 1.00000i
\n \\(149\\)\n \n −1.00000\n \n −\n \n 1.73205i\n −1.00000\n \n −\n \n 1.73205i\n −0.500000\n \n −\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n −0.500000\n \n −\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n \\(150\\)\n \n 0\n \n 0\n
\n \\(151\\)\n \n 0\n \n 0\n \n −0.866025\n \n −\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(152\\)\n \n 0\n \n 0\n
\n \\(153\\)\n \n −\n \n 1.00000i\n −\n \n 1.00000i
\n \\(154\\)\n \n 0\n \n 0\n
\n \\(155\\)\n \n 0\n \n 0\n
\n \\(156\\)\n \n 0\n \n 0\n
\n \\(157\\)\n \n 1.00000\n \n −\n \n 1.73205i\n 1.00000\n \n −\n \n 1.73205i\n 0.500000\n \n −\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n 0.500000\n \n −\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n \\(158\\)\n \n 0\n \n 0\n
\n \\(159\\)\n \n 0\n \n 0\n
\n \\(160\\)\n \n −1.00000\n \n −\n \n 1.00000i\n −1.00000\n \n −\n \n 1.00000i
\n \\(161\\)\n \n 0\n \n 0\n
\n \\(162\\)\n \n 1.00000i\n 1.00000i
\n \\(163\\)\n \n 0\n \n 0\n \n 0.258819\n \n −\n \n 0.965926i\n \\(-0.416667\\pi\\)\n
\n −0.258819\n \n +\n \n 0.965926i\n \\(0.583333\\pi\\)\n
\n \\(164\\)\n \n −1.36603\n \n +\n \n 0.366025i\n −1.36603\n \n +\n \n 0.366025i
\n \\(165\\)\n \n 0\n \n 0\n
\n \\(166\\)\n \n 0\n \n 0\n
\n \\(167\\)\n \n 0\n \n 0\n \n 0.707107\n \n −\n \n 0.707107i\n \\(-0.250000\\pi\\)\n
\n −0.707107\n \n +\n \n 0.707107i\n \\(0.750000\\pi\\)\n
\n \\(168\\)\n \n 0\n \n 0\n
\n \\(169\\)\n \n −1.00000\n \n −1.00000\n
\n \\(170\\)\n \n −0.366025\n \n +\n \n 1.36603i\n −0.366025\n \n +\n \n 1.36603i
\n \\(171\\)\n \n 0\n \n 0\n
\n \\(172\\)\n \n 0\n \n 0\n
\n \\(173\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i\n 0.866025\n \n −\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(174\\)\n \n 0\n \n 0\n
\n \\(175\\)\n \n 0\n \n 0\n
\n \\(176\\)\n \n 0\n \n 0\n
\n \\(177\\)\n \n 0\n \n 0\n
\n \\(178\\)\n \n 0\n \n 0\n
\n \\(179\\)\n \n 0\n \n 0\n \n −0.866025\n \n −\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(180\\)\n \n 0.366025\n \n −\n \n 1.36603i\n 0.366025\n \n −\n \n 1.36603i
\n \\(181\\)\n \n 1.00000\n \n +\n \n 1.00000i\n 1.00000\n \n +\n \n 1.00000i\n 1.00000\n \n \\(0\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(182\\)\n \n 0\n \n 0\n
\n \\(183\\)\n \n 0\n \n 0\n
\n \\(184\\)\n \n 0\n \n 0\n
\n \\(185\\)\n \n −1.73205\n \n −\n \n 1.00000i\n −1.73205\n \n −\n \n 1.00000i
\n \\(186\\)\n \n 0\n \n 0\n
\n \\(187\\)\n \n 0\n \n 0\n
\n \\(188\\)\n \n 0\n \n 0\n
\n \\(189\\)\n \n 0\n \n 0\n
\n \\(190\\)\n \n 0\n \n 0\n
\n \\(191\\)\n \n 0\n \n 0\n \n −0.500000\n \n −\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(192\\)\n \n 0\n \n 0\n
\n \\(193\\)\n \n −1.36603\n \n +\n \n 0.366025i\n −1.36603\n \n +\n \n 0.366025i\n −0.866025\n \n −\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(194\\)\n \n −0.366025\n \n +\n \n 1.36603i\n −0.366025\n \n +\n \n 1.36603i
\n \\(195\\)\n \n 0\n \n 0\n
\n \\(196\\)\n \n 0\n \n 0\n
\n \\(197\\)\n \n 1.00000\n \n +\n \n 1.00000i\n 1.00000\n \n +\n \n 1.00000i\n 1.00000\n \n \\(0\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(198\\)\n \n 0\n \n 0\n
\n \\(199\\)\n \n 0\n \n 0\n \n −0.258819\n \n −\n \n 0.965926i\n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \\(0.416667\\pi\\)\n
\n \\(200\\)\n \n −0.500000\n \n +\n \n 0.866025i\n −0.500000\n \n +\n \n 0.866025i
\n \\(201\\)\n \n 0\n \n 0\n
\n \\(202\\)\n \n 0\n \n 0\n
\n \\(203\\)\n \n 0\n \n 0\n
\n \\(204\\)\n \n 0\n \n 0\n
\n \\(205\\)\n \n 1.00000\n \n +\n \n 1.73205i\n 1.00000\n \n +\n \n 1.73205i
\n \\(206\\)\n \n 0\n \n 0\n
\n \\(207\\)\n \n 0\n \n 0\n
\n \\(208\\)\n \n 0\n \n 0\n
\n \\(209\\)\n \n 0\n \n 0\n
\n \\(210\\)\n \n 0\n \n 0\n
\n \\(211\\)\n \n 0\n \n 0\n \n −0.707107\n \n −\n \n 0.707107i\n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \\(0.250000\\pi\\)\n
\n \\(212\\)\n \n 0\n \n 0\n
\n \\(213\\)\n \n 0\n \n 0\n
\n \\(214\\)\n \n 0\n \n 0\n
\n \\(215\\)\n \n 0\n \n 0\n
\n \\(216\\)\n \n 0\n \n 0\n
\n \\(217\\)\n \n 0\n \n 0\n
\n \\(218\\)\n \n −1.00000\n \n +\n \n 1.00000i\n −1.00000\n \n +\n \n 1.00000i
\n \\(219\\)\n \n 0\n \n 0\n
\n \\(220\\)\n \n 0\n \n 0\n
\n \\(221\\)\n \n 0\n \n 0\n
\n \\(222\\)\n \n 0\n \n 0\n
\n \\(223\\)\n \n 0\n \n 0\n \n −\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(224\\)\n \n 0\n \n 0\n
\n \\(225\\)\n \n −1.00000\n \n −1.00000\n
\n \\(226\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i
\n \\(227\\)\n \n 0\n \n 0\n \n 0.965926\n \n −\n \n 0.258819i\n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \\(0.916667\\pi\\)\n
\n \\(228\\)\n \n 0\n \n 0\n
\n \\(229\\)\n \n −1.73205\n \n +\n \n 1.00000i\n −1.73205\n \n +\n \n 1.00000i\n −0.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(230\\)\n \n 0\n \n 0\n
\n \\(231\\)\n \n 0\n \n 0\n
\n \\(232\\)\n \n 1.00000\n \n +\n \n 1.00000i\n 1.00000\n \n +\n \n 1.00000i
\n \\(233\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i\n 0.866025\n \n −\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(234\\)\n \n 0\n \n 0\n
\n \\(235\\)\n \n 0\n \n 0\n
\n \\(236\\)\n \n 0\n \n 0\n
\n \\(237\\)\n \n 0\n \n 0\n
\n \\(238\\)\n \n 0\n \n 0\n
\n \\(239\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n −1.00000\n \n \\(\\pi\\)\n
\n \\(240\\)\n \n 0\n \n 0\n
\n \\(241\\)\n \n −0.366025\n \n −\n \n 1.36603i\n −0.366025\n \n −\n \n 1.36603i\n −0.866025\n \n −\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.500000\n \n −\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n \\(242\\)\n \n −0.500000\n \n +\n \n 0.866025i\n −0.500000\n \n +\n \n 0.866025i
\n \\(243\\)\n \n 0\n \n 0\n
\n \\(244\\)\n \n −1.00000\n \n −\n \n 1.00000i\n −1.00000\n \n −\n \n 1.00000i
\n \\(245\\)\n \n 0\n \n 0\n
\n \\(246\\)\n \n 0\n \n 0\n
\n \\(247\\)\n \n 0\n \n 0\n
\n \\(248\\)\n \n 0\n \n 0\n
\n \\(249\\)\n \n 0\n \n 0\n
\n \\(250\\)\n \n 0\n \n 0\n
\n \\(251\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n −1.00000\n \n \\(\\pi\\)\n
\n \\(252\\)\n \n 0\n \n 0\n
\n \\(253\\)\n \n 0\n \n 0\n
\n \\(254\\)\n \n 0\n \n 0\n
\n \\(255\\)\n \n 0\n \n 0\n
\n \\(256\\)\n \n −0.500000\n \n +\n \n 0.866025i\n −0.500000\n \n +\n \n 0.866025i
\n \\(257\\)\n \n 1.73205\n \n −\n \n 1.00000i\n 1.73205\n \n −\n \n 1.00000i\n 0.866025\n \n −\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n 0.866025\n \n −\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \\(258\\)\n \n 0\n \n 0\n
\n \\(259\\)\n \n 0\n \n 0\n
\n \\(260\\)\n \n 0\n \n 0\n
\n \\(261\\)\n \n −0.366025\n \n +\n \n 1.36603i\n −0.366025\n \n +\n \n 1.36603i
\n \\(262\\)\n \n 0\n \n 0\n
\n \\(263\\)\n \n 0\n \n 0\n \n −0.866025\n \n −\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(264\\)\n \n 0\n \n 0\n
\n \\(265\\)\n \n 0\n \n 0\n
\n \\(266\\)\n \n 0\n \n 0\n
\n \\(267\\)\n \n 0\n \n 0\n
\n \\(268\\)\n \n 0\n \n 0\n
\n \\(269\\)\n \n 0.366025\n \n +\n \n 1.36603i\n 0.366025\n \n +\n \n 1.36603i\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(270\\)\n \n 0\n \n 0\n
\n \\(271\\)\n \n 0\n \n 0\n \n −0.500000\n \n −\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(272\\)\n \n 1.00000\n \n 1.00000\n
\n \\(273\\)\n \n 0\n \n 0\n
\n \\(274\\)\n \n 0\n \n 0\n
\n \\(275\\)\n \n 0\n \n 0\n
\n \\(276\\)\n \n 0\n \n 0\n
\n \\(277\\)\n \n 0.366025\n \n +\n \n 1.36603i\n 0.366025\n \n +\n \n 1.36603i\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(278\\)\n \n 0\n \n 0\n
\n \\(279\\)\n \n 0\n \n 0\n
\n \\(280\\)\n \n 0\n \n 0\n
\n \\(281\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n −1.00000\n \n \\(\\pi\\)\n
\n \\(282\\)\n \n 0\n \n 0\n
\n \\(283\\)\n \n 0\n \n 0\n \n 0.965926\n \n −\n \n 0.258819i\n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \\(0.916667\\pi\\)\n
\n \\(284\\)\n \n 0\n \n 0\n
\n \\(285\\)\n \n 0\n \n 0\n
\n \\(286\\)\n \n 0\n \n 0\n
\n \\(287\\)\n \n 0\n \n 0\n
\n \\(288\\)\n \n −1.00000\n \n −1.00000\n
\n \\(289\\)\n \n −0.500000\n \n −\n \n 0.866025i\n −0.500000\n \n −\n \n 0.866025i
\n \\(290\\)\n \n 1.00000\n \n −\n \n 1.73205i\n 1.00000\n \n −\n \n 1.73205i
\n \\(291\\)\n \n 0\n \n 0\n
\n \\(292\\)\n \n −1.36603\n \n −\n \n 0.366025i\n −1.36603\n \n −\n \n 0.366025i
\n \\(293\\)\n \n 2.00000\n \n 2.00000\n \n 1.00000\n \n \\(0\\)\n
\n 1.00000\n \n \\(0\\)\n
\n \\(294\\)\n \n 0\n \n 0\n
\n \\(295\\)\n \n 0\n \n 0\n
\n \\(296\\)\n \n −0.366025\n \n +\n \n 1.36603i\n −0.366025\n \n +\n \n 1.36603i
\n \\(297\\)\n \n 0\n \n 0\n
\n \\(298\\)\n \n 1.73205\n \n +\n \n 1.00000i\n 1.73205\n \n +\n \n 1.00000i
\n \\(299\\)\n \n 0\n \n 0\n
\n \\(300\\)\n \n 0\n \n 0\n
\n \\(301\\)\n \n 0\n \n 0\n
\n \\(302\\)\n \n 0\n \n 0\n
\n \\(303\\)\n \n 0\n \n 0\n
\n \\(304\\)\n \n 0\n \n 0\n
\n \\(305\\)\n \n −1.00000\n \n +\n \n 1.73205i\n −1.00000\n \n +\n \n 1.73205i
\n \\(306\\)\n \n 0.500000\n \n +\n \n 0.866025i\n 0.500000\n \n +\n \n 0.866025i
\n \\(307\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n −1.00000\n \n \\(\\pi\\)\n
\n \\(308\\)\n \n 0\n \n 0\n
\n \\(309\\)\n \n 0\n \n 0\n
\n \\(310\\)\n \n 0\n \n 0\n
\n \\(311\\)\n \n 0\n \n 0\n \n −0.258819\n \n −\n \n 0.965926i\n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \\(0.416667\\pi\\)\n
\n \\(312\\)\n \n 0\n \n 0\n
\n \\(313\\)\n \n −0.366025\n \n +\n \n 1.36603i\n −0.366025\n \n +\n \n 1.36603i\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(314\\)\n \n 2.00000i\n 2.00000i
\n \\(315\\)\n \n 0\n \n 0\n
\n \\(316\\)\n \n 0\n \n 0\n
\n \\(317\\)\n \n 0.366025\n \n −\n \n 1.36603i\n 0.366025\n \n −\n \n 1.36603i\n −0.500000\n \n −\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.866025\n \n −\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \\(318\\)\n \n 0\n \n 0\n
\n \\(319\\)\n \n 0\n \n 0\n
\n \\(320\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i
\n \\(321\\)\n \n 0\n \n 0\n
\n \\(322\\)\n \n 0\n \n 0\n
\n \\(323\\)\n \n 0\n \n 0\n
\n \\(324\\)\n \n −0.500000\n \n −\n \n 0.866025i\n −0.500000\n \n −\n \n 0.866025i
\n \\(325\\)\n \n 0\n \n 0\n
\n \\(326\\)\n \n 0\n \n 0\n
\n \\(327\\)\n \n 0\n \n 0\n
\n \\(328\\)\n \n 1.00000\n \n −\n \n 1.00000i\n 1.00000\n \n −\n \n 1.00000i
\n \\(329\\)\n \n 0\n \n 0\n
\n \\(330\\)\n \n 0\n \n 0\n
\n \\(331\\)\n \n 0\n \n 0\n \n 0.866025\n \n −\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(332\\)\n \n 0\n \n 0\n
\n \\(333\\)\n \n −1.36603\n \n +\n \n 0.366025i\n −1.36603\n \n +\n \n 0.366025i
\n \\(334\\)\n \n 0\n \n 0\n
\n \\(335\\)\n \n 0\n \n 0\n
\n \\(336\\)\n \n 0\n \n 0\n
\n \\(337\\)\n \n 1.00000\n \n −\n \n 1.00000i\n 1.00000\n \n −\n \n 1.00000i\n −\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000\n \n \\(0\\)\n
\n \\(338\\)\n \n 0.866025\n \n −\n \n 0.500000i\n 0.866025\n \n −\n \n 0.500000i
\n \\(339\\)\n \n 0\n \n 0\n
\n \\(340\\)\n \n −0.366025\n \n −\n \n 1.36603i\n −0.366025\n \n −\n \n 1.36603i
\n \\(341\\)\n \n 0\n \n 0\n
\n \\(342\\)\n \n 0\n \n 0\n
\n \\(343\\)\n \n 0\n \n 0\n
\n \\(344\\)\n \n 0\n \n 0\n
\n \\(345\\)\n \n 0\n \n 0\n
\n \\(346\\)\n \n −1.36603\n \n +\n \n 0.366025i\n −1.36603\n \n +\n \n 0.366025i
\n \\(347\\)\n \n 0\n \n 0\n \n 0.965926\n \n −\n \n 0.258819i\n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \\(0.916667\\pi\\)\n
\n \\(348\\)\n \n 0\n \n 0\n
\n \\(349\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n −1.00000\n \n \\(\\pi\\)\n
\n \\(350\\)\n \n 0\n \n 0\n
\n \\(351\\)\n \n 0\n \n 0\n
\n \\(352\\)\n \n 0\n \n 0\n
\n \\(353\\)\n \n −1.00000\n \n +\n \n 1.73205i\n −1.00000\n \n +\n \n 1.73205i\n −0.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(354\\)\n \n 0\n \n 0\n
\n \\(355\\)\n \n 0\n \n 0\n
\n \\(356\\)\n \n 0\n \n 0\n
\n \\(357\\)\n \n 0\n \n 0\n
\n \\(358\\)\n \n 0\n \n 0\n
\n \\(359\\)\n \n 0\n \n 0\n \n 0.866025\n \n −\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(360\\)\n \n 0.366025\n \n +\n \n 1.36603i\n 0.366025\n \n +\n \n 1.36603i
\n \\(361\\)\n \n 0.500000\n \n −\n \n 0.866025i\n 0.500000\n \n −\n \n 0.866025i
\n \\(362\\)\n \n −1.36603\n \n −\n \n 0.366025i\n −1.36603\n \n −\n \n 0.366025i
\n \\(363\\)\n \n 0\n \n 0\n
\n \\(364\\)\n \n 0\n \n 0\n
\n \\(365\\)\n \n 2.00000i\n 2.00000i
\n \\(366\\)\n \n 0\n \n 0\n
\n \\(367\\)\n \n 0\n \n 0\n \n 0.965926\n \n −\n \n 0.258819i\n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \\(0.916667\\pi\\)\n
\n \\(368\\)\n \n 0\n \n 0\n
\n \\(369\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i
\n \\(370\\)\n \n 2.00000\n \n 2.00000\n
\n \\(371\\)\n \n 0\n \n 0\n
\n \\(372\\)\n \n 0\n \n 0\n
\n \\(373\\)\n \n 0\n \n 0\n \n 0.866025\n \n −\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(374\\)\n \n 0\n \n 0\n
\n \\(375\\)\n \n 0\n \n 0\n
\n \\(376\\)\n \n 0\n \n 0\n
\n \\(377\\)\n \n 0\n \n 0\n
\n \\(378\\)\n \n 0\n \n 0\n
\n \\(379\\)\n \n 0\n \n 0\n \n 0.707107\n \n −\n \n 0.707107i\n \\(-0.250000\\pi\\)\n
\n −0.707107\n \n +\n \n 0.707107i\n \\(0.750000\\pi\\)\n
\n \\(380\\)\n \n 0\n \n 0\n
\n \\(381\\)\n \n 0\n \n 0\n
\n \\(382\\)\n \n 0\n \n 0\n
\n \\(383\\)\n \n 0\n \n 0\n \n 0.866025\n \n −\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(384\\)\n \n 0\n \n 0\n
\n \\(385\\)\n \n 0\n \n 0\n
\n \\(386\\)\n \n 1.00000\n \n −\n \n 1.00000i\n 1.00000\n \n −\n \n 1.00000i
\n \\(387\\)\n \n 0\n \n 0\n
\n \\(388\\)\n \n −0.366025\n \n −\n \n 1.36603i\n −0.366025\n \n −\n \n 1.36603i
\n \\(389\\)\n \n −1.73205\n \n −\n \n 1.00000i\n −1.73205\n \n −\n \n 1.00000i\n −0.866025\n \n −\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n −0.866025\n \n −\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n \\(390\\)\n \n 0\n \n 0\n
\n \\(391\\)\n \n 0\n \n 0\n
\n \\(392\\)\n \n 0\n \n 0\n
\n \\(393\\)\n \n 0\n \n 0\n
\n \\(394\\)\n \n −1.36603\n \n −\n \n 0.366025i\n −1.36603\n \n −\n \n 0.366025i
\n \\(395\\)\n \n 0\n \n 0\n
\n \\(396\\)\n \n 0\n \n 0\n
\n \\(397\\)\n \n 0.366025\n \n −\n \n 1.36603i\n 0.366025\n \n −\n \n 1.36603i\n −0.500000\n \n −\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.866025\n \n −\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \\(398\\)\n \n 0\n \n 0\n
\n \\(399\\)\n \n 0\n \n 0\n
\n \\(400\\)\n \n −\n \n 1.00000i\n −\n \n 1.00000i
\n \\(401\\)\n \n 0.366025\n \n −\n \n 1.36603i\n 0.366025\n \n −\n \n 1.36603i\n −0.500000\n \n −\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.866025\n \n −\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \\(402\\)\n \n 0\n \n 0\n
\n \\(403\\)\n \n 0\n \n 0\n
\n \\(404\\)\n \n 0\n \n 0\n
\n \\(405\\)\n \n −1.00000\n \n +\n \n 1.00000i\n −1.00000\n \n +\n \n 1.00000i
\n \\(406\\)\n \n 0\n \n 0\n
\n \\(407\\)\n \n 0\n \n 0\n
\n \\(408\\)\n \n 0\n \n 0\n
\n \\(409\\)\n \n −1.00000\n \n +\n \n 1.73205i\n −1.00000\n \n +\n \n 1.73205i\n −0.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(410\\)\n \n −1.73205\n \n −\n \n 1.00000i\n −1.73205\n \n −\n \n 1.00000i
\n \\(411\\)\n \n 0\n \n 0\n
\n \\(412\\)\n \n 0\n \n 0\n
\n \\(413\\)\n \n 0\n \n 0\n
\n \\(414\\)\n \n 0\n \n 0\n
\n \\(415\\)\n \n 0\n \n 0\n
\n \\(416\\)\n \n 0\n \n 0\n
\n \\(417\\)\n \n 0\n \n 0\n
\n \\(418\\)\n \n 0\n \n 0\n
\n \\(419\\)\n \n 0\n \n 0\n \n −0.707107\n \n −\n \n 0.707107i\n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \\(0.250000\\pi\\)\n
\n \\(420\\)\n \n 0\n \n 0\n
\n \\(421\\)\n \n 0\n \n 0\n \n −\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(422\\)\n \n 0\n \n 0\n
\n \\(423\\)\n \n 0\n \n 0\n
\n \\(424\\)\n \n 0\n \n 0\n
\n \\(425\\)\n \n −0.866025\n \n +\n \n 0.500000i\n −0.866025\n \n +\n \n 0.500000i
\n \\(426\\)\n \n 0\n \n 0\n
\n \\(427\\)\n \n 0\n \n 0\n
\n \\(428\\)\n \n 0\n \n 0\n
\n \\(429\\)\n \n 0\n \n 0\n
\n \\(430\\)\n \n 0\n \n 0\n
\n \\(431\\)\n \n 0\n \n 0\n \n 0.965926\n \n −\n \n 0.258819i\n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \\(0.916667\\pi\\)\n
\n \\(432\\)\n \n 0\n \n 0\n
\n \\(433\\)\n \n 2.00000i\n 2.00000i\n 1.00000i\n \\(0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(434\\)\n \n 0\n \n 0\n
\n \\(435\\)\n \n 0\n \n 0\n
\n \\(436\\)\n \n 0.366025\n \n −\n \n 1.36603i\n 0.366025\n \n −\n \n 1.36603i
\n \\(437\\)\n \n 0\n \n 0\n
\n \\(438\\)\n \n 0\n \n 0\n
\n \\(439\\)\n \n 0\n \n 0\n \n −0.965926\n \n −\n \n 0.258819i\n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \\(0.0833333\\pi\\)\n
\n \\(440\\)\n \n 0\n \n 0\n
\n \\(441\\)\n \n 0\n \n 0\n
\n \\(442\\)\n \n 0\n \n 0\n
\n \\(443\\)\n \n 0\n \n 0\n \n −0.500000\n \n −\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(444\\)\n \n 0\n \n 0\n
\n \\(445\\)\n \n 0\n \n 0\n
\n \\(446\\)\n \n 0\n \n 0\n
\n \\(447\\)\n \n 0\n \n 0\n
\n \\(448\\)\n \n 0\n \n 0\n
\n \\(449\\)\n \n −1.00000\n \n −\n \n 1.00000i\n −1.00000\n \n −\n \n 1.00000i\n −\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n −1.00000\n \n \\(\\pi\\)\n
\n \\(450\\)\n \n 0.866025\n \n −\n \n 0.500000i\n 0.866025\n \n −\n \n 0.500000i
\n \\(451\\)\n \n 0\n \n 0\n
\n \\(452\\)\n \n −1.36603\n \n +\n \n 0.366025i\n −1.36603\n \n +\n \n 0.366025i
\n \\(453\\)\n \n 0\n \n 0\n
\n \\(454\\)\n \n 0\n \n 0\n
\n \\(455\\)\n \n 0\n \n 0\n
\n \\(456\\)\n \n 0\n \n 0\n
\n \\(457\\)\n \n −1.73205\n \n +\n \n 1.00000i\n −1.73205\n \n +\n \n 1.00000i\n −0.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(458\\)\n \n 1.00000\n \n −\n \n 1.73205i\n 1.00000\n \n −\n \n 1.73205i
\n \\(459\\)\n \n 0\n \n 0\n
\n \\(460\\)\n \n 0\n \n 0\n
\n \\(461\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n −1.00000\n \n \\(\\pi\\)\n
\n \\(462\\)\n \n 0\n \n 0\n
\n \\(463\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n −1.00000\n \n \\(\\pi\\)\n
\n \\(464\\)\n \n −1.36603\n \n −\n \n 0.366025i\n −1.36603\n \n −\n \n 0.366025i
\n \\(465\\)\n \n 0\n \n 0\n
\n \\(466\\)\n \n −1.36603\n \n +\n \n 0.366025i\n −1.36603\n \n +\n \n 0.366025i
\n \\(467\\)\n \n 0\n \n 0\n \n 0.866025\n \n −\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(468\\)\n \n 0\n \n 0\n
\n \\(469\\)\n \n 0\n \n 0\n
\n \\(470\\)\n \n 0\n \n 0\n
\n \\(471\\)\n \n 0\n \n 0\n
\n \\(472\\)\n \n 0\n \n 0\n
\n \\(473\\)\n \n 0\n \n 0\n
\n \\(474\\)\n \n 0\n \n 0\n
\n \\(475\\)\n \n 0\n \n 0\n
\n \\(476\\)\n \n 0\n \n 0\n
\n \\(477\\)\n \n 0\n \n 0\n
\n \\(478\\)\n \n 0\n \n 0\n
\n \\(479\\)\n \n 0\n \n 0\n \n −0.258819\n \n −\n \n 0.965926i\n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \\(0.416667\\pi\\)\n
\n \\(480\\)\n \n 0\n \n 0\n
\n \\(481\\)\n \n 0\n \n 0\n
\n \\(482\\)\n \n 1.00000\n \n +\n \n 1.00000i\n 1.00000\n \n +\n \n 1.00000i
\n \\(483\\)\n \n 0\n \n 0\n
\n \\(484\\)\n \n −\n \n 1.00000i\n −\n \n 1.00000i
\n \\(485\\)\n \n −1.73205\n \n +\n \n 1.00000i\n −1.73205\n \n +\n \n 1.00000i
\n \\(486\\)\n \n 0\n \n 0\n
\n \\(487\\)\n \n 0\n \n 0\n \n 0.965926\n \n −\n \n 0.258819i\n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \\(0.916667\\pi\\)\n
\n \\(488\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i
\n \\(489\\)\n \n 0\n \n 0\n
\n \\(490\\)\n \n 0\n \n 0\n
\n \\(491\\)\n \n 0\n \n 0\n \n −\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(492\\)\n \n 0\n \n 0\n
\n \\(493\\)\n \n 0.366025\n \n +\n \n 1.36603i\n 0.366025\n \n +\n \n 1.36603i
\n \\(494\\)\n \n 0\n \n 0\n
\n \\(495\\)\n \n 0\n \n 0\n
\n \\(496\\)\n \n 0\n \n 0\n
\n \\(497\\)\n \n 0\n \n 0\n
\n \\(498\\)\n \n 0\n \n 0\n
\n \\(499\\)\n \n 0\n \n 0\n \n 0.258819\n \n −\n \n 0.965926i\n \\(-0.416667\\pi\\)\n
\n −0.258819\n \n +\n \n 0.965926i\n \\(0.583333\\pi\\)\n
\n \\(500\\)\n \n 0\n \n 0\n
\n \\(501\\)\n \n 0\n \n 0\n
\n \\(502\\)\n \n 0\n \n 0\n
\n \\(503\\)\n \n 0\n \n 0\n \n −0.707107\n \n −\n \n 0.707107i\n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \\(0.250000\\pi\\)\n
\n \\(504\\)\n \n 0\n \n 0\n
\n \\(505\\)\n \n 0\n \n 0\n
\n \\(506\\)\n \n 0\n \n 0\n
\n \\(507\\)\n \n 0\n \n 0\n
\n \\(508\\)\n \n 0\n \n 0\n
\n \\(509\\)\n \n −1.00000\n \n −\n \n 1.73205i\n −1.00000\n \n −\n \n 1.73205i\n −0.500000\n \n −\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n −0.500000\n \n −\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n \\(510\\)\n \n 0\n \n 0\n
\n \\(511\\)\n \n 0\n \n 0\n
\n \\(512\\)\n \n −\n \n 1.00000i\n −\n \n 1.00000i
\n \\(513\\)\n \n 0\n \n 0\n
\n \\(514\\)\n \n −1.00000\n \n +\n \n 1.73205i\n −1.00000\n \n +\n \n 1.73205i
\n \\(515\\)\n \n 0\n \n 0\n
\n \\(516\\)\n \n 0\n \n 0\n
\n \\(517\\)\n \n 0\n \n 0\n
\n \\(518\\)\n \n 0\n \n 0\n
\n \\(519\\)\n \n 0\n \n 0\n
\n \\(520\\)\n \n 0\n \n 0\n
\n \\(521\\)\n \n 1.36603\n \n −\n \n 0.366025i\n 1.36603\n \n −\n \n 0.366025i\n 0.500000\n \n −\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(522\\)\n \n −0.366025\n \n −\n \n 1.36603i\n −0.366025\n \n −\n \n 1.36603i
\n \\(523\\)\n \n 0\n \n 0\n \n −0.500000\n \n −\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(524\\)\n \n 0\n \n 0\n
\n \\(525\\)\n \n 0\n \n 0\n
\n \\(526\\)\n \n 0\n \n 0\n
\n \\(527\\)\n \n 0\n \n 0\n
\n \\(528\\)\n \n 0\n \n 0\n
\n \\(529\\)\n \n −0.866025\n \n −\n \n 0.500000i\n −0.866025\n \n −\n \n 0.500000i
\n \\(530\\)\n \n 0\n \n 0\n
\n \\(531\\)\n \n 0\n \n 0\n
\n \\(532\\)\n \n 0\n \n 0\n
\n \\(533\\)\n \n 0\n \n 0\n
\n \\(534\\)\n \n 0\n \n 0\n
\n \\(535\\)\n \n 0\n \n 0\n
\n \\(536\\)\n \n 0\n \n 0\n
\n \\(537\\)\n \n 0\n \n 0\n
\n \\(538\\)\n \n −1.00000\n \n −\n \n 1.00000i\n −1.00000\n \n −\n \n 1.00000i
\n \\(539\\)\n \n 0\n \n 0\n
\n \\(540\\)\n \n 0\n \n 0\n
\n \\(541\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i\n 0.866025\n \n −\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(542\\)\n \n 0\n \n 0\n
\n \\(543\\)\n \n 0\n \n 0\n
\n \\(544\\)\n \n −0.866025\n \n +\n \n 0.500000i\n −0.866025\n \n +\n \n 0.500000i
\n \\(545\\)\n \n −2.00000\n \n −2.00000\n
\n \\(546\\)\n \n 0\n \n 0\n
\n \\(547\\)\n \n 0\n \n 0\n \n 0.707107\n \n −\n \n 0.707107i\n \\(-0.250000\\pi\\)\n
\n −0.707107\n \n +\n \n 0.707107i\n \\(0.750000\\pi\\)\n
\n \\(548\\)\n \n 0\n \n 0\n
\n \\(549\\)\n \n 0.366025\n \n +\n \n 1.36603i\n 0.366025\n \n +\n \n 1.36603i
\n \\(550\\)\n \n 0\n \n 0\n
\n \\(551\\)\n \n 0\n \n 0\n
\n \\(552\\)\n \n 0\n \n 0\n
\n \\(553\\)\n \n 0\n \n 0\n
\n \\(554\\)\n \n −1.00000\n \n −\n \n 1.00000i\n −1.00000\n \n −\n \n 1.00000i
\n \\(555\\)\n \n 0\n \n 0\n
\n \\(556\\)\n \n 0\n \n 0\n
\n \\(557\\)\n \n 0\n \n 0\n \n −0.866025\n \n −\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(558\\)\n \n 0\n \n 0\n
\n \\(559\\)\n \n 0\n \n 0\n
\n \\(560\\)\n \n 0\n \n 0\n
\n \\(561\\)\n \n 0\n \n 0\n
\n \\(562\\)\n \n 0\n \n 0\n
\n \\(563\\)\n \n 0\n \n 0\n \n −0.866025\n \n −\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(564\\)\n \n 0\n \n 0\n
\n \\(565\\)\n \n 1.00000\n \n +\n \n 1.73205i\n 1.00000\n \n +\n \n 1.73205i
\n \\(566\\)\n \n 0\n \n 0\n
\n \\(567\\)\n \n 0\n \n 0\n
\n \\(568\\)\n \n 0\n \n 0\n
\n \\(569\\)\n \n 0\n \n 0\n \n −0.500000\n \n −\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(570\\)\n \n 0\n \n 0\n
\n \\(571\\)\n \n 0\n \n 0\n \n 0.965926\n \n −\n \n 0.258819i\n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \\(0.916667\\pi\\)\n
\n \\(572\\)\n \n 0\n \n 0\n
\n \\(573\\)\n \n 0\n \n 0\n
\n \\(574\\)\n \n 0\n \n 0\n
\n \\(575\\)\n \n 0\n \n 0\n
\n \\(576\\)\n \n 0.866025\n \n −\n \n 0.500000i\n 0.866025\n \n −\n \n 0.500000i
\n \\(577\\)\n \n 0\n \n 0\n \n −0.866025\n \n −\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(578\\)\n \n 0.866025\n \n +\n \n 0.500000i\n 0.866025\n \n +\n \n 0.500000i
\n \\(579\\)\n \n 0\n \n 0\n
\n \\(580\\)\n \n 2.00000i\n 2.00000i
\n \\(581\\)\n \n 0\n \n 0\n
\n \\(582\\)\n \n 0\n \n 0\n
\n \\(583\\)\n \n 0\n \n 0\n
\n \\(584\\)\n \n 1.36603\n \n −\n \n 0.366025i\n 1.36603\n \n −\n \n 0.366025i
\n \\(585\\)\n \n 0\n \n 0\n
\n \\(586\\)\n \n −1.73205\n \n +\n \n 1.00000i\n −1.73205\n \n +\n \n 1.00000i
\n \\(587\\)\n \n 0\n \n 0\n \n −\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(588\\)\n \n 0\n \n 0\n
\n \\(589\\)\n \n 0\n \n 0\n
\n \\(590\\)\n \n 0\n \n 0\n
\n \\(591\\)\n \n 0\n \n 0\n
\n \\(592\\)\n \n −0.366025\n \n −\n \n 1.36603i\n −0.366025\n \n −\n \n 1.36603i
\n \\(593\\)\n \n 0\n \n 0\n \n −0.500000\n \n −\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(594\\)\n \n 0\n \n 0\n
\n \\(595\\)\n \n 0\n \n 0\n
\n \\(596\\)\n \n −2.00000\n \n −2.00000\n
\n \\(597\\)\n \n 0\n \n 0\n
\n \\(598\\)\n \n 0\n \n 0\n
\n \\(599\\)\n \n 0\n \n 0\n \n 0.500000\n \n −\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(600\\)\n \n 0\n \n 0\n
\n \\(601\\)\n \n −1.00000\n \n −\n \n 1.00000i\n −1.00000\n \n −\n \n 1.00000i\n −\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n −1.00000\n \n \\(\\pi\\)\n
\n \\(602\\)\n \n 0\n \n 0\n
\n \\(603\\)\n \n 0\n \n 0\n
\n \\(604\\)\n \n 0\n \n 0\n
\n \\(605\\)\n \n −1.36603\n \n +\n \n 0.366025i\n −1.36603\n \n +\n \n 0.366025i
\n \\(606\\)\n \n 0\n \n 0\n
\n \\(607\\)\n \n 0\n \n 0\n \n −0.965926\n \n −\n \n 0.258819i\n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \\(0.0833333\\pi\\)\n
\n \\(608\\)\n \n 0\n \n 0\n
\n \\(609\\)\n \n 0\n \n 0\n
\n \\(610\\)\n \n −\n \n 2.00000i\n −\n \n 2.00000i
\n \\(611\\)\n \n 0\n \n 0\n
\n \\(612\\)\n \n −0.866025\n \n −\n \n 0.500000i\n −0.866025\n \n −\n \n 0.500000i
\n \\(613\\)\n \n −1.00000\n \n +\n \n 1.73205i\n −1.00000\n \n +\n \n 1.73205i\n −0.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(614\\)\n \n 0\n \n 0\n
\n \\(615\\)\n \n 0\n \n 0\n
\n \\(616\\)\n \n 0\n \n 0\n
\n \\(617\\)\n \n −1.00000\n \n +\n \n 1.00000i\n −1.00000\n \n +\n \n 1.00000i\n 1.00000i\n \\(0.5\\pi\\)\n
\n −1.00000\n \n \\(\\pi\\)\n
\n \\(618\\)\n \n 0\n \n 0\n
\n \\(619\\)\n \n 0\n \n 0\n \n 0.965926\n \n −\n \n 0.258819i\n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \\(0.916667\\pi\\)\n
\n \\(620\\)\n \n 0\n \n 0\n
\n \\(621\\)\n \n 0\n \n 0\n
\n \\(622\\)\n \n 0\n \n 0\n
\n \\(623\\)\n \n 0\n \n 0\n
\n \\(624\\)\n \n 0\n \n 0\n
\n \\(625\\)\n \n −0.500000\n \n −\n \n 0.866025i\n −0.500000\n \n −\n \n 0.866025i
\n \\(626\\)\n \n −0.366025\n \n −\n \n 1.36603i\n −0.366025\n \n −\n \n 1.36603i
\n \\(627\\)\n \n 0\n \n 0\n
\n \\(628\\)\n \n −1.00000\n \n −\n \n 1.73205i\n −1.00000\n \n −\n \n 1.73205i
\n \\(629\\)\n \n −1.00000\n \n +\n \n 1.00000i\n −1.00000\n \n +\n \n 1.00000i
\n \\(630\\)\n \n 0\n \n 0\n
\n \\(631\\)\n \n 0\n \n 0\n \n −\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(632\\)\n \n 0\n \n 0\n
\n \\(633\\)\n \n 0\n \n 0\n
\n \\(634\\)\n \n 0.366025\n \n +\n \n 1.36603i\n 0.366025\n \n +\n \n 1.36603i
\n \\(635\\)\n \n 0\n \n 0\n
\n \\(636\\)\n \n 0\n \n 0\n
\n \\(637\\)\n \n 0\n \n 0\n
\n \\(638\\)\n \n 0\n \n 0\n
\n \\(639\\)\n \n 0\n \n 0\n
\n \\(640\\)\n \n −1.36603\n \n +\n \n 0.366025i\n −1.36603\n \n +\n \n 0.366025i
\n \\(641\\)\n \n −0.366025\n \n −\n \n 1.36603i\n −0.366025\n \n −\n \n 1.36603i\n −0.866025\n \n −\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.500000\n \n −\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n \\(642\\)\n \n 0\n \n 0\n
\n \\(643\\)\n \n 0\n \n 0\n \n 0.707107\n \n −\n \n 0.707107i\n \\(-0.250000\\pi\\)\n
\n −0.707107\n \n +\n \n 0.707107i\n \\(0.750000\\pi\\)\n
\n \\(644\\)\n \n 0\n \n 0\n
\n \\(645\\)\n \n 0\n \n 0\n
\n \\(646\\)\n \n 0\n \n 0\n
\n \\(647\\)\n \n 0\n \n 0\n \n 0.500000\n \n −\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(648\\)\n \n 0.866025\n \n +\n \n 0.500000i\n 0.866025\n \n +\n \n 0.500000i
\n \\(649\\)\n \n 0\n \n 0\n
\n \\(650\\)\n \n 0\n \n 0\n
\n \\(651\\)\n \n 0\n \n 0\n
\n \\(652\\)\n \n 0\n \n 0\n
\n \\(653\\)\n \n 0.366025\n \n −\n \n 1.36603i\n 0.366025\n \n −\n \n 1.36603i\n −0.500000\n \n −\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.866025\n \n −\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n \\(654\\)\n \n 0\n \n 0\n
\n \\(655\\)\n \n 0\n \n 0\n
\n \\(656\\)\n \n −0.366025\n \n +\n \n 1.36603i\n −0.366025\n \n +\n \n 1.36603i
\n \\(657\\)\n \n 1.00000\n \n +\n \n 1.00000i\n 1.00000\n \n +\n \n 1.00000i
\n \\(658\\)\n \n 0\n \n 0\n
\n \\(659\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n −1.00000\n \n \\(\\pi\\)\n
\n \\(660\\)\n \n 0\n \n 0\n
\n \\(661\\)\n \n 0\n \n 0\n \n 0.500000\n \n −\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(662\\)\n \n 0\n \n 0\n
\n \\(663\\)\n \n 0\n \n 0\n
\n \\(664\\)\n \n 0\n \n 0\n
\n \\(665\\)\n \n 0\n \n 0\n
\n \\(666\\)\n \n 1.00000\n \n −\n \n 1.00000i\n 1.00000\n \n −\n \n 1.00000i
\n \\(667\\)\n \n 0\n \n 0\n
\n \\(668\\)\n \n 0\n \n 0\n
\n \\(669\\)\n \n 0\n \n 0\n
\n \\(670\\)\n \n 0\n \n 0\n
\n \\(671\\)\n \n 0\n \n 0\n
\n \\(672\\)\n \n 0\n \n 0\n
\n \\(673\\)\n \n −1.00000\n \n −\n \n 1.00000i\n −1.00000\n \n −\n \n 1.00000i\n −\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n −1.00000\n \n \\(\\pi\\)\n
\n \\(674\\)\n \n −0.366025\n \n +\n \n 1.36603i\n −0.366025\n \n +\n \n 1.36603i
\n \\(675\\)\n \n 0\n \n 0\n
\n \\(676\\)\n \n −0.500000\n \n +\n \n 0.866025i\n −0.500000\n \n +\n \n 0.866025i
\n \\(677\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i\n 0.866025\n \n −\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(678\\)\n \n 0\n \n 0\n
\n \\(679\\)\n \n 0\n \n 0\n
\n \\(680\\)\n \n 1.00000\n \n +\n \n 1.00000i\n 1.00000\n \n +\n \n 1.00000i
\n \\(681\\)\n \n 0\n \n 0\n
\n \\(682\\)\n \n 0\n \n 0\n
\n \\(683\\)\n \n 0\n \n 0\n \n −0.258819\n \n −\n \n 0.965926i\n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \\(0.416667\\pi\\)\n
\n \\(684\\)\n \n 0\n \n 0\n
\n \\(685\\)\n \n 0\n \n 0\n
\n \\(686\\)\n \n 0\n \n 0\n
\n \\(687\\)\n \n 0\n \n 0\n
\n \\(688\\)\n \n 0\n \n 0\n
\n \\(689\\)\n \n 0\n \n 0\n
\n \\(690\\)\n \n 0\n \n 0\n
\n \\(691\\)\n \n 0\n \n 0\n \n 0.258819\n \n −\n \n 0.965926i\n \\(-0.416667\\pi\\)\n
\n −0.258819\n \n +\n \n 0.965926i\n \\(0.583333\\pi\\)\n
\n \\(692\\)\n \n 1.00000\n \n −\n \n 1.00000i\n 1.00000\n \n −\n \n 1.00000i
\n \\(693\\)\n \n 0\n \n 0\n
\n \\(694\\)\n \n 0\n \n 0\n
\n \\(695\\)\n \n 0\n \n 0\n
\n \\(696\\)\n \n 0\n \n 0\n
\n \\(697\\)\n \n 1.36603\n \n −\n \n 0.366025i\n 1.36603\n \n −\n \n 0.366025i
\n \\(698\\)\n \n 0\n \n 0\n
\n \\(699\\)\n \n 0\n \n 0\n
\n \\(700\\)\n \n 0\n \n 0\n
\n \\(701\\)\n \n 0\n \n 0\n \n −\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(702\\)\n \n 0\n \n 0\n
\n \\(703\\)\n \n 0\n \n 0\n
\n \\(704\\)\n \n 0\n \n 0\n
\n \\(705\\)\n \n 0\n \n 0\n
\n \\(706\\)\n \n −\n \n 2.00000i\n −\n \n 2.00000i
\n \\(707\\)\n \n 0\n \n 0\n
\n \\(708\\)\n \n 0\n \n 0\n
\n \\(709\\)\n \n −1.36603\n \n −\n \n 0.366025i\n −1.36603\n \n −\n \n 0.366025i\n −0.500000\n \n −\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(710\\)\n \n 0\n \n 0\n
\n \\(711\\)\n \n 0\n \n 0\n
\n \\(712\\)\n \n 0\n \n 0\n
\n \\(713\\)\n \n 0\n \n 0\n
\n \\(714\\)\n \n 0\n \n 0\n
\n \\(715\\)\n \n 0\n \n 0\n
\n \\(716\\)\n \n 0\n \n 0\n
\n \\(717\\)\n \n 0\n \n 0\n
\n \\(718\\)\n \n 0\n \n 0\n
\n \\(719\\)\n \n 0\n \n 0\n \n −0.965926\n \n −\n \n 0.258819i\n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \\(0.0833333\\pi\\)\n
\n \\(720\\)\n \n −1.00000\n \n −\n \n 1.00000i\n −1.00000\n \n −\n \n 1.00000i
\n \\(721\\)\n \n 0\n \n 0\n
\n \\(722\\)\n \n 1.00000i\n 1.00000i
\n \\(723\\)\n \n 0\n \n 0\n
\n \\(724\\)\n \n 1.36603\n \n −\n \n 0.366025i\n 1.36603\n \n −\n \n 0.366025i
\n \\(725\\)\n \n 1.36603\n \n −\n \n 0.366025i\n 1.36603\n \n −\n \n 0.366025i
\n \\(726\\)\n \n 0\n \n 0\n
\n \\(727\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n −1.00000\n \n \\(\\pi\\)\n
\n \\(728\\)\n \n 0\n \n 0\n
\n \\(729\\)\n \n 1.00000i\n 1.00000i
\n \\(730\\)\n \n −1.00000\n \n −\n \n 1.73205i\n −1.00000\n \n −\n \n 1.73205i
\n \\(731\\)\n \n 0\n \n 0\n
\n \\(732\\)\n \n 0\n \n 0\n
\n \\(733\\)\n \n 0\n \n 0\n \n −0.500000\n \n −\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(734\\)\n \n 0\n \n 0\n
\n \\(735\\)\n \n 0\n \n 0\n
\n \\(736\\)\n \n 0\n \n 0\n
\n \\(737\\)\n \n 0\n \n 0\n
\n \\(738\\)\n \n −1.36603\n \n +\n \n 0.366025i\n −1.36603\n \n +\n \n 0.366025i
\n \\(739\\)\n \n 0\n \n 0\n \n −0.866025\n \n −\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(740\\)\n \n −1.73205\n \n +\n \n 1.00000i\n −1.73205\n \n +\n \n 1.00000i
\n \\(741\\)\n \n 0\n \n 0\n
\n \\(742\\)\n \n 0\n \n 0\n
\n \\(743\\)\n \n 0\n \n 0\n \n 0.707107\n \n −\n \n 0.707107i\n \\(-0.250000\\pi\\)\n
\n −0.707107\n \n +\n \n 0.707107i\n \\(0.750000\\pi\\)\n
\n \\(744\\)\n \n 0\n \n 0\n
\n \\(745\\)\n \n 0.732051\n \n +\n \n 2.73205i\n 0.732051\n \n +\n \n 2.73205i
\n \\(746\\)\n \n 0\n \n 0\n
\n \\(747\\)\n \n 0\n \n 0\n
\n \\(748\\)\n \n 0\n \n 0\n
\n \\(749\\)\n \n 0\n \n 0\n
\n \\(750\\)\n \n 0\n \n 0\n
\n \\(751\\)\n \n 0\n \n 0\n \n −0.965926\n \n −\n \n 0.258819i\n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \\(0.0833333\\pi\\)\n
\n \\(752\\)\n \n 0\n \n 0\n
\n \\(753\\)\n \n 0\n \n 0\n
\n \\(754\\)\n \n 0\n \n 0\n
\n \\(755\\)\n \n 0\n \n 0\n
\n \\(756\\)\n \n 0\n \n 0\n
\n \\(757\\)\n \n 2.00000i\n 2.00000i\n 1.00000i\n \\(0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(758\\)\n \n 0\n \n 0\n
\n \\(759\\)\n \n 0\n \n 0\n
\n \\(760\\)\n \n 0\n \n 0\n
\n \\(761\\)\n \n 0\n \n 0\n \n 0.866025\n \n −\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(762\\)\n \n 0\n \n 0\n
\n \\(763\\)\n \n 0\n \n 0\n
\n \\(764\\)\n \n 0\n \n 0\n
\n \\(765\\)\n \n −0.366025\n \n +\n \n 1.36603i\n −0.366025\n \n +\n \n 1.36603i
\n \\(766\\)\n \n 0\n \n 0\n
\n \\(767\\)\n \n 0\n \n 0\n
\n \\(768\\)\n \n 0\n \n 0\n
\n \\(769\\)\n \n 0\n \n 0\n \n −\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(770\\)\n \n 0\n \n 0\n
\n \\(771\\)\n \n 0\n \n 0\n
\n \\(772\\)\n \n −0.366025\n \n +\n \n 1.36603i\n −0.366025\n \n +\n \n 1.36603i
\n \\(773\\)\n \n −1.73205\n \n −\n \n 1.00000i\n −1.73205\n \n −\n \n 1.00000i\n −0.866025\n \n −\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n −0.866025\n \n −\n \n 0.500000i\n \\(-0.833333\\pi\\)\n
\n \\(774\\)\n \n 0\n \n 0\n
\n \\(775\\)\n \n 0\n \n 0\n
\n \\(776\\)\n \n 1.00000\n \n +\n \n 1.00000i\n 1.00000\n \n +\n \n 1.00000i
\n \\(777\\)\n \n 0\n \n 0\n
\n \\(778\\)\n \n 2.00000\n \n 2.00000\n
\n \\(779\\)\n \n 0\n \n 0\n
\n \\(780\\)\n \n 0\n \n 0\n
\n \\(781\\)\n \n 0\n \n 0\n
\n \\(782\\)\n \n 0\n \n 0\n
\n \\(783\\)\n \n 0\n \n 0\n
\n \\(784\\)\n \n 0\n \n 0\n
\n \\(785\\)\n \n −2.00000\n \n +\n \n 2.00000i\n −2.00000\n \n +\n \n 2.00000i
\n \\(786\\)\n \n 0\n \n 0\n
\n \\(787\\)\n \n 0\n \n 0\n \n −0.258819\n \n −\n \n 0.965926i\n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \\(0.416667\\pi\\)\n
\n \\(788\\)\n \n 1.36603\n \n −\n \n 0.366025i\n 1.36603\n \n −\n \n 0.366025i
\n \\(789\\)\n \n 0\n \n 0\n
\n \\(790\\)\n \n 0\n \n 0\n
\n \\(791\\)\n \n 0\n \n 0\n
\n \\(792\\)\n \n 0\n \n 0\n
\n \\(793\\)\n \n 0\n \n 0\n
\n \\(794\\)\n \n 0.366025\n \n +\n \n 1.36603i\n 0.366025\n \n +\n \n 1.36603i
\n \\(795\\)\n \n 0\n \n 0\n
\n \\(796\\)\n \n 0\n \n 0\n
\n \\(797\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n −1.00000\n \n \\(\\pi\\)\n
\n \\(798\\)\n \n 0\n \n 0\n
\n \\(799\\)\n \n 0\n \n 0\n
\n \\(800\\)\n \n 0.500000\n \n +\n \n 0.866025i\n 0.500000\n \n +\n \n 0.866025i
\n \\(801\\)\n \n 0\n \n 0\n
\n \\(802\\)\n \n 0.366025\n \n +\n \n 1.36603i\n 0.366025\n \n +\n \n 1.36603i
\n \\(803\\)\n \n 0\n \n 0\n
\n \\(804\\)\n \n 0\n \n 0\n
\n \\(805\\)\n \n 0\n \n 0\n
\n \\(806\\)\n \n 0\n \n 0\n
\n \\(807\\)\n \n 0\n \n 0\n
\n \\(808\\)\n \n 0\n \n 0\n
\n \\(809\\)\n \n 1.36603\n \n −\n \n 0.366025i\n 1.36603\n \n −\n \n 0.366025i\n 0.500000\n \n −\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(810\\)\n \n 0.366025\n \n −\n \n 1.36603i\n 0.366025\n \n −\n \n 1.36603i
\n \\(811\\)\n \n 0\n \n 0\n \n 0.707107\n \n −\n \n 0.707107i\n \\(-0.250000\\pi\\)\n
\n −0.707107\n \n +\n \n 0.707107i\n \\(0.750000\\pi\\)\n
\n \\(812\\)\n \n 0\n \n 0\n
\n \\(813\\)\n \n 0\n \n 0\n
\n \\(814\\)\n \n 0\n \n 0\n
\n \\(815\\)\n \n 0\n \n 0\n
\n \\(816\\)\n \n 0\n \n 0\n
\n \\(817\\)\n \n 0\n \n 0\n
\n \\(818\\)\n \n −\n \n 2.00000i\n −\n \n 2.00000i
\n \\(819\\)\n \n 0\n \n 0\n
\n \\(820\\)\n \n 2.00000\n \n 2.00000\n
\n \\(821\\)\n \n −1.36603\n \n −\n \n 0.366025i\n −1.36603\n \n −\n \n 0.366025i\n −0.500000\n \n −\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(822\\)\n \n 0\n \n 0\n
\n \\(823\\)\n \n 0\n \n 0\n \n 0.965926\n \n −\n \n 0.258819i\n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \\(0.916667\\pi\\)\n
\n \\(824\\)\n \n 0\n \n 0\n
\n \\(825\\)\n \n 0\n \n 0\n
\n \\(826\\)\n \n 0\n \n 0\n
\n \\(827\\)\n \n 0\n \n 0\n \n −0.707107\n \n −\n \n 0.707107i\n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \\(0.250000\\pi\\)\n
\n \\(828\\)\n \n 0\n \n 0\n
\n \\(829\\)\n \n 1.00000\n \n −\n \n 1.73205i\n 1.00000\n \n −\n \n 1.73205i\n 0.500000\n \n −\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n 0.500000\n \n −\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n \\(830\\)\n \n 0\n \n 0\n
\n \\(831\\)\n \n 0\n \n 0\n
\n \\(832\\)\n \n 0\n \n 0\n
\n \\(833\\)\n \n 0\n \n 0\n
\n \\(834\\)\n \n 0\n \n 0\n
\n \\(835\\)\n \n 0\n \n 0\n
\n \\(836\\)\n \n 0\n \n 0\n
\n \\(837\\)\n \n 0\n \n 0\n
\n \\(838\\)\n \n 0\n \n 0\n
\n \\(839\\)\n \n 0\n \n 0\n \n −0.707107\n \n −\n \n 0.707107i\n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \\(0.250000\\pi\\)\n
\n \\(840\\)\n \n 0\n \n 0\n
\n \\(841\\)\n \n −\n \n 1.00000i\n −\n \n 1.00000i
\n \\(842\\)\n \n 0\n \n 0\n
\n \\(843\\)\n \n 0\n \n 0\n
\n \\(844\\)\n \n 0\n \n 0\n
\n \\(845\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i
\n \\(846\\)\n \n 0\n \n 0\n
\n \\(847\\)\n \n 0\n \n 0\n
\n \\(848\\)\n \n 0\n \n 0\n
\n \\(849\\)\n \n 0\n \n 0\n
\n \\(850\\)\n \n 0.500000\n \n −\n \n 0.866025i\n 0.500000\n \n −\n \n 0.866025i
\n \\(851\\)\n \n 0\n \n 0\n
\n \\(852\\)\n \n 0\n \n 0\n
\n \\(853\\)\n \n 1.00000\n \n −\n \n 1.00000i\n 1.00000\n \n −\n \n 1.00000i\n −\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000\n \n \\(0\\)\n
\n \\(854\\)\n \n 0\n \n 0\n
\n \\(855\\)\n \n 0\n \n 0\n
\n \\(856\\)\n \n 0\n \n 0\n
\n \\(857\\)\n \n 1.36603\n \n −\n \n 0.366025i\n 1.36603\n \n −\n \n 0.366025i\n 0.500000\n \n −\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(858\\)\n \n 0\n \n 0\n
\n \\(859\\)\n \n 0\n \n 0\n \n 0.866025\n \n −\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(860\\)\n \n 0\n \n 0\n
\n \\(861\\)\n \n 0\n \n 0\n
\n \\(862\\)\n \n 0\n \n 0\n
\n \\(863\\)\n \n 0\n \n 0\n \n −0.500000\n \n −\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(864\\)\n \n 0\n \n 0\n
\n \\(865\\)\n \n −1.73205\n \n −\n \n 1.00000i\n −1.73205\n \n −\n \n 1.00000i
\n \\(866\\)\n \n −1.00000\n \n −\n \n 1.73205i\n −1.00000\n \n −\n \n 1.73205i
\n \\(867\\)\n \n 0\n \n 0\n
\n \\(868\\)\n \n 0\n \n 0\n
\n \\(869\\)\n \n 0\n \n 0\n
\n \\(870\\)\n \n 0\n \n 0\n
\n \\(871\\)\n \n 0\n \n 0\n
\n \\(872\\)\n \n 0.366025\n \n +\n \n 1.36603i\n 0.366025\n \n +\n \n 1.36603i
\n \\(873\\)\n \n −0.366025\n \n +\n \n 1.36603i\n −0.366025\n \n +\n \n 1.36603i
\n \\(874\\)\n \n 0\n \n 0\n
\n \\(875\\)\n \n 0\n \n 0\n
\n \\(876\\)\n \n 0\n \n 0\n
\n \\(877\\)\n \n −0.366025\n \n +\n \n 1.36603i\n −0.366025\n \n +\n \n 1.36603i\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(878\\)\n \n 0\n \n 0\n
\n \\(879\\)\n \n 0\n \n 0\n
\n \\(880\\)\n \n 0\n \n 0\n
\n \\(881\\)\n \n −1.00000\n \n +\n \n 1.00000i\n −1.00000\n \n +\n \n 1.00000i\n 1.00000i\n \\(0.5\\pi\\)\n
\n −1.00000\n \n \\(\\pi\\)\n
\n \\(882\\)\n \n 0\n \n 0\n
\n \\(883\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n −1.00000\n \n \\(\\pi\\)\n
\n \\(884\\)\n \n 0\n \n 0\n
\n \\(885\\)\n \n 0\n \n 0\n
\n \\(886\\)\n \n 0\n \n 0\n
\n \\(887\\)\n \n 0\n \n 0\n \n −0.965926\n \n −\n \n 0.258819i\n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \\(0.0833333\\pi\\)\n
\n \\(888\\)\n \n 0\n \n 0\n
\n \\(889\\)\n \n 0\n \n 0\n
\n \\(890\\)\n \n 0\n \n 0\n
\n \\(891\\)\n \n 0\n \n 0\n
\n \\(892\\)\n \n 0\n \n 0\n
\n \\(893\\)\n \n 0\n \n 0\n
\n \\(894\\)\n \n 0\n \n 0\n
\n \\(895\\)\n \n 0\n \n 0\n
\n \\(896\\)\n \n 0\n \n 0\n
\n \\(897\\)\n \n 0\n \n 0\n
\n \\(898\\)\n \n 1.36603\n \n +\n \n 0.366025i\n 1.36603\n \n +\n \n 0.366025i
\n \\(899\\)\n \n 0\n \n 0\n
\n \\(900\\)\n \n −0.500000\n \n +\n \n 0.866025i\n −0.500000\n \n +\n \n 0.866025i
\n \\(901\\)\n \n 0\n \n 0\n
\n \\(902\\)\n \n 0\n \n 0\n
\n \\(903\\)\n \n 0\n \n 0\n
\n \\(904\\)\n \n 1.00000\n \n −\n \n 1.00000i\n 1.00000\n \n −\n \n 1.00000i
\n \\(905\\)\n \n −1.00000\n \n −\n \n 1.73205i\n −1.00000\n \n −\n \n 1.73205i
\n \\(906\\)\n \n 0\n \n 0\n
\n \\(907\\)\n \n 0\n \n 0\n \n 0.965926\n \n −\n \n 0.258819i\n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \\(0.916667\\pi\\)\n
\n \\(908\\)\n \n 0\n \n 0\n
\n \\(909\\)\n \n 0\n \n 0\n
\n \\(910\\)\n \n 0\n \n 0\n
\n \\(911\\)\n \n 0\n \n 0\n \n −0.707107\n \n −\n \n 0.707107i\n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \\(0.250000\\pi\\)\n
\n \\(912\\)\n \n 0\n \n 0\n
\n \\(913\\)\n \n 0\n \n 0\n
\n \\(914\\)\n \n 1.00000\n \n −\n \n 1.73205i\n 1.00000\n \n −\n \n 1.73205i
\n \\(915\\)\n \n 0\n \n 0\n
\n \\(916\\)\n \n 2.00000i\n 2.00000i
\n \\(917\\)\n \n 0\n \n 0\n
\n \\(918\\)\n \n 0\n \n 0\n
\n \\(919\\)\n \n 0\n \n 0\n \n −0.500000\n \n −\n \n 0.866025i\n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n \\(920\\)\n \n 0\n \n 0\n
\n \\(921\\)\n \n 0\n \n 0\n
\n \\(922\\)\n \n 0\n \n 0\n
\n \\(923\\)\n \n 0\n \n 0\n
\n \\(924\\)\n \n 0\n \n 0\n
\n \\(925\\)\n \n 1.00000\n \n +\n \n 1.00000i\n 1.00000\n \n +\n \n 1.00000i
\n \\(926\\)\n \n 0\n \n 0\n
\n \\(927\\)\n \n 0\n \n 0\n
\n \\(928\\)\n \n 1.36603\n \n −\n \n 0.366025i\n 1.36603\n \n −\n \n 0.366025i
\n \\(929\\)\n \n −0.366025\n \n +\n \n 1.36603i\n −0.366025\n \n +\n \n 1.36603i\n 0.500000\n \n +\n \n 0.866025i\n \\(0.333333\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(930\\)\n \n 0\n \n 0\n
\n \\(931\\)\n \n 0\n \n 0\n
\n \\(932\\)\n \n 1.00000\n \n −\n \n 1.00000i\n 1.00000\n \n −\n \n 1.00000i
\n \\(933\\)\n \n 0\n \n 0\n
\n \\(934\\)\n \n 0\n \n 0\n
\n \\(935\\)\n \n 0\n \n 0\n
\n \\(936\\)\n \n 0\n \n 0\n
\n \\(937\\)\n \n 0\n \n 0\n \n 1.00000\n \n \\(0\\)\n
\n −1.00000\n \n \\(\\pi\\)\n
\n \\(938\\)\n \n 0\n \n 0\n
\n \\(939\\)\n \n 0\n \n 0\n
\n \\(940\\)\n \n 0\n \n 0\n
\n \\(941\\)\n \n 1.36603\n \n −\n \n 0.366025i\n 1.36603\n \n −\n \n 0.366025i\n 0.500000\n \n −\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(942\\)\n \n 0\n \n 0\n
\n \\(943\\)\n \n 0\n \n 0\n
\n \\(944\\)\n \n 0\n \n 0\n
\n \\(945\\)\n \n 0\n \n 0\n
\n \\(946\\)\n \n 0\n \n 0\n
\n \\(947\\)\n \n 0\n \n 0\n \n −0.965926\n \n −\n \n 0.258819i\n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \\(0.0833333\\pi\\)\n
\n \\(948\\)\n \n 0\n \n 0\n
\n \\(949\\)\n \n 0\n \n 0\n
\n \\(950\\)\n \n 0\n \n 0\n
\n \\(951\\)\n \n 0\n \n 0\n
\n \\(952\\)\n \n 0\n \n 0\n
\n \\(953\\)\n \n 0\n \n 0\n \n −\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(954\\)\n \n 0\n \n 0\n
\n \\(955\\)\n \n 0\n \n 0\n
\n \\(956\\)\n \n 0\n \n 0\n
\n \\(957\\)\n \n 0\n \n 0\n
\n \\(958\\)\n \n 0\n \n 0\n
\n \\(959\\)\n \n 0\n \n 0\n
\n \\(960\\)\n \n 0\n \n 0\n
\n \\(961\\)\n \n −0.866025\n \n +\n \n 0.500000i\n −0.866025\n \n +\n \n 0.500000i
\n \\(962\\)\n \n 0\n \n 0\n
\n \\(963\\)\n \n 0\n \n 0\n
\n \\(964\\)\n \n −1.36603\n \n −\n \n 0.366025i\n −1.36603\n \n −\n \n 0.366025i
\n \\(965\\)\n \n 2.00000\n \n 2.00000\n
\n \\(966\\)\n \n 0\n \n 0\n
\n \\(967\\)\n \n 0\n \n 0\n \n −\n \n 1.00000i\n \\(-0.5\\pi\\)\n
\n 1.00000i\n \\(0.5\\pi\\)\n
\n \\(968\\)\n \n 0.500000\n \n +\n \n 0.866025i\n 0.500000\n \n +\n \n 0.866025i
\n \\(969\\)\n \n 0\n \n 0\n
\n \\(970\\)\n \n 1.00000\n \n −\n \n 1.73205i\n 1.00000\n \n −\n \n 1.73205i
\n \\(971\\)\n \n 0\n \n 0\n \n 0.866025\n \n −\n \n 0.500000i\n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \\(0.833333\\pi\\)\n
\n \\(972\\)\n \n 0\n \n 0\n
\n \\(973\\)\n \n 0\n \n 0\n
\n \\(974\\)\n \n 0\n \n 0\n
\n \\(975\\)\n \n 0\n \n 0\n
\n \\(976\\)\n \n −1.36603\n \n +\n \n 0.366025i\n −1.36603\n \n +\n \n 0.366025i
\n \\(977\\)\n \n 0\n \n 0\n \n 0.500000\n \n −\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \\(0.666667\\pi\\)\n
\n \\(978\\)\n \n 0\n \n 0\n
\n \\(979\\)\n \n 0\n \n 0\n
\n \\(980\\)\n \n 0\n \n 0\n
\n \\(981\\)\n \n −1.00000\n \n +\n \n 1.00000i\n −1.00000\n \n +\n \n 1.00000i
\n \\(982\\)\n \n 0\n \n 0\n
\n \\(983\\)\n \n 0\n \n 0\n \n −0.258819\n \n −\n \n 0.965926i\n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \\(0.416667\\pi\\)\n
\n \\(984\\)\n \n 0\n \n 0\n
\n \\(985\\)\n \n −1.00000\n \n −\n \n 1.73205i\n −1.00000\n \n −\n \n 1.73205i
\n \\(986\\)\n \n −1.00000\n \n −\n \n 1.00000i\n −1.00000\n \n −\n \n 1.00000i
\n \\(987\\)\n \n 0\n \n 0\n
\n \\(988\\)\n \n 0\n \n 0\n
\n \\(989\\)\n \n 0\n \n 0\n
\n \\(990\\)\n \n 0\n \n 0\n
\n \\(991\\)\n \n 0\n \n 0\n \n −0.258819\n \n −\n \n 0.965926i\n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \\(0.416667\\pi\\)\n
\n \\(992\\)\n \n 0\n \n 0\n
\n \\(993\\)\n \n 0\n \n 0\n
\n \\(994\\)\n \n 0\n \n 0\n
\n \\(995\\)\n \n 0\n \n 0\n
\n \\(996\\)\n \n 0\n \n 0\n
\n \\(997\\)\n \n 1.36603\n \n −\n \n 0.366025i\n 1.36603\n \n −\n \n 0.366025i\n 0.500000\n \n −\n \n 0.866025i\n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \\(0.166667\\pi\\)\n
\n \\(998\\)\n \n 0\n \n 0\n
\n \\(999\\)\n \n 0\n \n 0\n
", "content": {"html": "
$n$$a_n$$a_n / n^{(k-1)/2}$$\\alpha_n$$\\theta_n$
$p$$a_p$$a_p / p^{(k-1)/2}$$\\alpha_p$$\\theta_p$
$2$−0.866025+0.500000i−0.866025+0.500000i
$3$00−0.2588190.965926i$-0.583333\\pi$
0.258819+0.965926i$0.416667\\pi$
$4$0.5000000.866025i0.5000000.866025i
$5$−1.366030.366025i−1.366030.366025i−0.5000000.866025i$-0.666667\\pi$
−0.866025+0.500000i$0.833333\\pi$
$6$00
$7$00
$8$1.00000i1.00000i
$9$−0.866025+0.500000i−0.866025+0.500000i
$10$1.366030.366025i1.366030.366025i
$11$000.9659260.258819i$-0.0833333\\pi$
−0.965926+0.258819i$0.916667\\pi$
$12$00
$13$001.00000i$-0.5\\pi$
1.00000i$0.5\\pi$
$14$00
$15$00
$16$−0.5000000.866025i−0.5000000.866025i
$17$−0.500000+0.866025i−0.500000+0.866025i
$18$0.5000000.866025i0.5000000.866025i
$19$000.8660250.500000i$-0.166667\\pi$
−0.866025+0.500000i$0.833333\\pi$
$20$−1.00000+1.00000i−1.00000+1.00000i
$21$00
$22$00
$23$000.2588190.965926i$-0.416667\\pi$
−0.258819+0.965926i$0.583333\\pi$
$24$00
$25$0.866025+0.500000i0.866025+0.500000i
$26$00
$27$00
$28$00
$29$1.000001.00000i1.000001.00000i1.00000i$-0.5\\pi$
1.00000$0$
$30$00
$31$00−0.2588190.965926i$-0.583333\\pi$
0.258819+0.965926i$0.416667\\pi$
$32$0.866025+0.500000i0.866025+0.500000i
$33$00
$34$1.00000i1.00000i
$35$00
$36$1.00000i1.00000i
$37$1.36603+0.366025i1.36603+0.366025i0.8660250.500000i$-0.166667\\pi$
0.500000+0.866025i$0.333333\\pi$
$38$00
$39$00
$40$0.3660251.36603i0.3660251.36603i
$41$−1.000001.00000i−1.000001.00000i1.00000i$-0.5\\pi$
−1.00000$\\pi$
$42$00
$43$001.00000i$-0.5\\pi$
1.00000i$0.5\\pi$
$44$00
$45$1.366030.366025i1.366030.366025i
$46$00
$47$00−0.5000000.866025i$-0.666667\\pi$
0.500000+0.866025i$0.333333\\pi$
$48$00
$49$00
$50$−1.00000−1.00000
$51$00
$52$00
$53$000.5000000.866025i$-0.333333\\pi$
−0.500000+0.866025i$0.666667\\pi$
$54$00
$55$00
$56$00
$57$00
$58$−0.366025+1.36603i−0.366025+1.36603i
$59$00−0.8660250.500000i$-0.833333\\pi$
0.866025+0.500000i$0.166667\\pi$
$60$00
$61$0.3660251.36603i0.3660251.36603i−0.5000000.866025i$-0.666667\\pi$
0.8660250.500000i$-0.166667\\pi$
$62$00
$63$00
$64$−1.00000−1.00000
$65$00
$66$00
$67$000.5000000.866025i$-0.333333\\pi$
−0.500000+0.866025i$0.666667\\pi$
$68$0.500000+0.866025i0.500000+0.866025i
$69$00
$70$00
$71$000.7071070.707107i$-0.250000\\pi$
−0.707107+0.707107i$0.750000\\pi$
$72$−0.5000000.866025i−0.5000000.866025i
$73$−0.3660251.36603i−0.3660251.36603i−0.8660250.500000i$-0.833333\\pi$
0.5000000.866025i$-0.333333\\pi$
$74$−1.36603+0.366025i−1.36603+0.366025i
$75$00
$76$00
$77$00
$78$00
$79$000.2588190.965926i$-0.416667\\pi$
−0.258819+0.965926i$0.583333\\pi$
$80$0.366025+1.36603i0.366025+1.36603i
$81$0.5000000.866025i0.5000000.866025i
$82$1.36603+0.366025i1.36603+0.366025i
$83$001.00000i$-0.5\\pi$
1.00000i$0.5\\pi$
$84$00
$85$1.000001.00000i1.000001.00000i
$86$00
$87$00
$88$00
$89$000.8660250.500000i$-0.166667\\pi$
−0.866025+0.500000i$0.833333\\pi$
$90$−1.00000+1.00000i−1.00000+1.00000i
$91$00
$92$00
$93$00
$94$00
$95$00
$96$00
$97$1.000001.00000i1.000001.00000i1.00000i$-0.5\\pi$
1.00000$0$
$98$00
$99$00
$100$0.8660250.500000i0.8660250.500000i
$101$00−0.8660250.500000i$-0.833333\\pi$
0.866025+0.500000i$0.166667\\pi$
$102$00
$103$00−0.5000000.866025i$-0.666667\\pi$
0.500000+0.866025i$0.333333\\pi$
$104$00
$105$00
$106$00
$107$00−0.9659260.258819i$-0.916667\\pi$
0.965926+0.258819i$0.0833333\\pi$
$108$00
$109$1.366030.366025i1.366030.366025i0.5000000.866025i$-0.333333\\pi$
0.866025+0.500000i$0.166667\\pi$
$110$00
$111$00
$112$00
$113$−1.000001.00000i−1.000001.00000i1.00000i$-0.5\\pi$
−1.00000$\\pi$
$114$00
$115$00
$116$−0.3660251.36603i−0.3660251.36603i
$117$00
$118$00
$119$00
$120$00
$121$0.8660250.500000i0.8660250.500000i
$122$0.366025+1.36603i0.366025+1.36603i
$123$00
$124$00
$125$00
$126$00
$127$001.00000i$-0.5\\pi$
1.00000i$0.5\\pi$
$128$0.8660250.500000i0.8660250.500000i
$129$00
$130$00
$131$00−0.9659260.258819i$-0.916667\\pi$
0.965926+0.258819i$0.0833333\\pi$
$132$00
$133$00
$134$00
$135$00
$136$−0.8660250.500000i−0.8660250.500000i
$137$00−0.8660250.500000i$-0.833333\\pi$
0.866025+0.500000i$0.166667\\pi$
$138$00
$139$000.7071070.707107i$-0.250000\\pi$
−0.707107+0.707107i$0.750000\\pi$
$140$00
$141$00
$142$00
$143$00
$144$0.866025+0.500000i0.866025+0.500000i
$145$−1.73205+1.00000i−1.73205+1.00000i
$146$1.00000+1.00000i1.00000+1.00000i
$147$00
$148$1.000001.00000i1.000001.00000i
$149$−1.000001.73205i−1.000001.73205i−0.5000000.866025i$-0.666667\\pi$
−0.5000000.866025i$-0.666667\\pi$
$150$00
$151$00−0.8660250.500000i$-0.833333\\pi$
0.866025+0.500000i$0.166667\\pi$
$152$00
$153$1.00000i1.00000i
$154$00
$155$00
$156$00
$157$1.000001.73205i1.000001.73205i0.5000000.866025i$-0.333333\\pi$
0.5000000.866025i$-0.333333\\pi$
$158$00
$159$00
$160$−1.000001.00000i−1.000001.00000i
$161$00
$162$1.00000i1.00000i
$163$000.2588190.965926i$-0.416667\\pi$
−0.258819+0.965926i$0.583333\\pi$
$164$−1.36603+0.366025i−1.36603+0.366025i
$165$00
$166$00
$167$000.7071070.707107i$-0.250000\\pi$
−0.707107+0.707107i$0.750000\\pi$
$168$00
$169$−1.00000−1.00000
$170$−0.366025+1.36603i−0.366025+1.36603i
$171$00
$172$00
$173$1.36603+0.366025i1.36603+0.366025i0.8660250.500000i$-0.166667\\pi$
0.500000+0.866025i$0.333333\\pi$
$174$00
$175$00
$176$00
$177$00
$178$00
$179$00−0.8660250.500000i$-0.833333\\pi$
0.866025+0.500000i$0.166667\\pi$
$180$0.3660251.36603i0.3660251.36603i
$181$1.00000+1.00000i1.00000+1.00000i1.00000$0$
1.00000i$0.5\\pi$
$182$00
$183$00
$184$00
$185$−1.732051.00000i−1.732051.00000i
$186$00
$187$00
$188$00
$189$00
$190$00
$191$00−0.5000000.866025i$-0.666667\\pi$
0.500000+0.866025i$0.333333\\pi$
$192$00
$193$−1.36603+0.366025i−1.36603+0.366025i−0.8660250.500000i$-0.833333\\pi$
−0.500000+0.866025i$0.666667\\pi$
$194$−0.366025+1.36603i−0.366025+1.36603i
$195$00
$196$00
$197$1.00000+1.00000i1.00000+1.00000i1.00000$0$
1.00000i$0.5\\pi$
$198$00
$199$00−0.2588190.965926i$-0.583333\\pi$
0.258819+0.965926i$0.416667\\pi$
$200$−0.500000+0.866025i−0.500000+0.866025i
$201$00
$202$00
$203$00
$204$00
$205$1.00000+1.73205i1.00000+1.73205i
$206$00
$207$00
$208$00
$209$00
$210$00
$211$00−0.7071070.707107i$-0.750000\\pi$
0.707107+0.707107i$0.250000\\pi$
$212$00
$213$00
$214$00
$215$00
$216$00
$217$00
$218$−1.00000+1.00000i−1.00000+1.00000i
$219$00
$220$00
$221$00
$222$00
$223$001.00000i$-0.5\\pi$
1.00000i$0.5\\pi$
$224$00
$225$−1.00000−1.00000
$226$1.36603+0.366025i1.36603+0.366025i
$227$000.9659260.258819i$-0.0833333\\pi$
−0.965926+0.258819i$0.916667\\pi$
$228$00
$229$−1.73205+1.00000i−1.73205+1.00000i−0.866025+0.500000i$0.833333\\pi$
−0.866025+0.500000i$0.833333\\pi$
$230$00
$231$00
$232$1.00000+1.00000i1.00000+1.00000i
$233$1.36603+0.366025i1.36603+0.366025i0.8660250.500000i$-0.166667\\pi$
0.500000+0.866025i$0.333333\\pi$
$234$00
$235$00
$236$00
$237$00
$238$00
$239$001.00000$0$
−1.00000$\\pi$
$240$00
$241$−0.3660251.36603i−0.3660251.36603i−0.8660250.500000i$-0.833333\\pi$
0.5000000.866025i$-0.333333\\pi$
$242$−0.500000+0.866025i−0.500000+0.866025i
$243$00
$244$−1.000001.00000i−1.000001.00000i
$245$00
$246$00
$247$00
$248$00
$249$00
$250$00
$251$001.00000$0$
−1.00000$\\pi$
$252$00
$253$00
$254$00
$255$00
$256$−0.500000+0.866025i−0.500000+0.866025i
$257$1.732051.00000i1.732051.00000i0.8660250.500000i$-0.166667\\pi$
0.8660250.500000i$-0.166667\\pi$
$258$00
$259$00
$260$00
$261$−0.366025+1.36603i−0.366025+1.36603i
$262$00
$263$00−0.8660250.500000i$-0.833333\\pi$
0.866025+0.500000i$0.166667\\pi$
$264$00
$265$00
$266$00
$267$00
$268$00
$269$0.366025+1.36603i0.366025+1.36603i0.866025+0.500000i$0.166667\\pi$
−0.500000+0.866025i$0.666667\\pi$
$270$00
$271$00−0.5000000.866025i$-0.666667\\pi$
0.500000+0.866025i$0.333333\\pi$
$272$1.000001.00000
$273$00
$274$00
$275$00
$276$00
$277$0.366025+1.36603i0.366025+1.36603i0.866025+0.500000i$0.166667\\pi$
−0.500000+0.866025i$0.666667\\pi$
$278$00
$279$00
$280$00
$281$001.00000$0$
−1.00000$\\pi$
$282$00
$283$000.9659260.258819i$-0.0833333\\pi$
−0.965926+0.258819i$0.916667\\pi$
$284$00
$285$00
$286$00
$287$00
$288$−1.00000−1.00000
$289$−0.5000000.866025i−0.5000000.866025i
$290$1.000001.73205i1.000001.73205i
$291$00
$292$−1.366030.366025i−1.366030.366025i
$293$2.000002.000001.00000$0$
1.00000$0$
$294$00
$295$00
$296$−0.366025+1.36603i−0.366025+1.36603i
$297$00
$298$1.73205+1.00000i1.73205+1.00000i
$299$00
$300$00
$301$00
$302$00
$303$00
$304$00
$305$−1.00000+1.73205i−1.00000+1.73205i
$306$0.500000+0.866025i0.500000+0.866025i
$307$001.00000$0$
−1.00000$\\pi$
$308$00
$309$00
$310$00
$311$00−0.2588190.965926i$-0.583333\\pi$
0.258819+0.965926i$0.416667\\pi$
$312$00
$313$−0.366025+1.36603i−0.366025+1.36603i0.500000+0.866025i$0.333333\\pi$
−0.866025+0.500000i$0.833333\\pi$
$314$2.00000i2.00000i
$315$00
$316$00
$317$0.3660251.36603i0.3660251.36603i−0.5000000.866025i$-0.666667\\pi$
0.8660250.500000i$-0.166667\\pi$
$318$00
$319$00
$320$1.36603+0.366025i1.36603+0.366025i
$321$00
$322$00
$323$00
$324$−0.5000000.866025i−0.5000000.866025i
$325$00
$326$00
$327$00
$328$1.000001.00000i1.000001.00000i
$329$00
$330$00
$331$000.8660250.500000i$-0.166667\\pi$
−0.866025+0.500000i$0.833333\\pi$
$332$00
$333$−1.36603+0.366025i−1.36603+0.366025i
$334$00
$335$00
$336$00
$337$1.000001.00000i1.000001.00000i1.00000i$-0.5\\pi$
1.00000$0$
$338$0.8660250.500000i0.8660250.500000i
$339$00
$340$−0.3660251.36603i−0.3660251.36603i
$341$00
$342$00
$343$00
$344$00
$345$00
$346$−1.36603+0.366025i−1.36603+0.366025i
$347$000.9659260.258819i$-0.0833333\\pi$
−0.965926+0.258819i$0.916667\\pi$
$348$00
$349$001.00000$0$
−1.00000$\\pi$
$350$00
$351$00
$352$00
$353$−1.00000+1.73205i−1.00000+1.73205i−0.500000+0.866025i$0.666667\\pi$
−0.500000+0.866025i$0.666667\\pi$
$354$00
$355$00
$356$00
$357$00
$358$00
$359$000.8660250.500000i$-0.166667\\pi$
−0.866025+0.500000i$0.833333\\pi$
$360$0.366025+1.36603i0.366025+1.36603i
$361$0.5000000.866025i0.5000000.866025i
$362$−1.366030.366025i−1.366030.366025i
$363$00
$364$00
$365$2.00000i2.00000i
$366$00
$367$000.9659260.258819i$-0.0833333\\pi$
−0.965926+0.258819i$0.916667\\pi$
$368$00
$369$1.36603+0.366025i1.36603+0.366025i
$370$2.000002.00000
$371$00
$372$00
$373$000.8660250.500000i$-0.166667\\pi$
−0.866025+0.500000i$0.833333\\pi$
$374$00
$375$00
$376$00
$377$00
$378$00
$379$000.7071070.707107i$-0.250000\\pi$
−0.707107+0.707107i$0.750000\\pi$
$380$00
$381$00
$382$00
$383$000.8660250.500000i$-0.166667\\pi$
−0.866025+0.500000i$0.833333\\pi$
$384$00
$385$00
$386$1.000001.00000i1.000001.00000i
$387$00
$388$−0.3660251.36603i−0.3660251.36603i
$389$−1.732051.00000i−1.732051.00000i−0.8660250.500000i$-0.833333\\pi$
−0.8660250.500000i$-0.833333\\pi$
$390$00
$391$00
$392$00
$393$00
$394$−1.366030.366025i−1.366030.366025i
$395$00
$396$00
$397$0.3660251.36603i0.3660251.36603i−0.5000000.866025i$-0.666667\\pi$
0.8660250.500000i$-0.166667\\pi$
$398$00
$399$00
$400$1.00000i1.00000i
$401$0.3660251.36603i0.3660251.36603i−0.5000000.866025i$-0.666667\\pi$
0.8660250.500000i$-0.166667\\pi$
$402$00
$403$00
$404$00
$405$−1.00000+1.00000i−1.00000+1.00000i
$406$00
$407$00
$408$00
$409$−1.00000+1.73205i−1.00000+1.73205i−0.500000+0.866025i$0.666667\\pi$
−0.500000+0.866025i$0.666667\\pi$
$410$−1.732051.00000i−1.732051.00000i
$411$00
$412$00
$413$00
$414$00
$415$00
$416$00
$417$00
$418$00
$419$00−0.7071070.707107i$-0.750000\\pi$
0.707107+0.707107i$0.250000\\pi$
$420$00
$421$001.00000i$-0.5\\pi$
1.00000i$0.5\\pi$
$422$00
$423$00
$424$00
$425$−0.866025+0.500000i−0.866025+0.500000i
$426$00
$427$00
$428$00
$429$00
$430$00
$431$000.9659260.258819i$-0.0833333\\pi$
−0.965926+0.258819i$0.916667\\pi$
$432$00
$433$2.00000i2.00000i1.00000i$0.5\\pi$
1.00000i$0.5\\pi$
$434$00
$435$00
$436$0.3660251.36603i0.3660251.36603i
$437$00
$438$00
$439$00−0.9659260.258819i$-0.916667\\pi$
0.965926+0.258819i$0.0833333\\pi$
$440$00
$441$00
$442$00
$443$00−0.5000000.866025i$-0.666667\\pi$
0.500000+0.866025i$0.333333\\pi$
$444$00
$445$00
$446$00
$447$00
$448$00
$449$−1.000001.00000i−1.000001.00000i1.00000i$-0.5\\pi$
−1.00000$\\pi$
$450$0.8660250.500000i0.8660250.500000i
$451$00
$452$−1.36603+0.366025i−1.36603+0.366025i
$453$00
$454$00
$455$00
$456$00
$457$−1.73205+1.00000i−1.73205+1.00000i−0.866025+0.500000i$0.833333\\pi$
−0.866025+0.500000i$0.833333\\pi$
$458$1.000001.73205i1.000001.73205i
$459$00
$460$00
$461$001.00000$0$
−1.00000$\\pi$
$462$00
$463$001.00000$0$
−1.00000$\\pi$
$464$−1.366030.366025i−1.366030.366025i
$465$00
$466$−1.36603+0.366025i−1.36603+0.366025i
$467$000.8660250.500000i$-0.166667\\pi$
−0.866025+0.500000i$0.833333\\pi$
$468$00
$469$00
$470$00
$471$00
$472$00
$473$00
$474$00
$475$00
$476$00
$477$00
$478$00
$479$00−0.2588190.965926i$-0.583333\\pi$
0.258819+0.965926i$0.416667\\pi$
$480$00
$481$00
$482$1.00000+1.00000i1.00000+1.00000i
$483$00
$484$1.00000i1.00000i
$485$−1.73205+1.00000i−1.73205+1.00000i
$486$00
$487$000.9659260.258819i$-0.0833333\\pi$
−0.965926+0.258819i$0.916667\\pi$
$488$1.36603+0.366025i1.36603+0.366025i
$489$00
$490$00
$491$001.00000i$-0.5\\pi$
1.00000i$0.5\\pi$
$492$00
$493$0.366025+1.36603i0.366025+1.36603i
$494$00
$495$00
$496$00
$497$00
$498$00
$499$000.2588190.965926i$-0.416667\\pi$
−0.258819+0.965926i$0.583333\\pi$
$500$00
$501$00
$502$00
$503$00−0.7071070.707107i$-0.750000\\pi$
0.707107+0.707107i$0.250000\\pi$
$504$00
$505$00
$506$00
$507$00
$508$00
$509$−1.000001.73205i−1.000001.73205i−0.5000000.866025i$-0.666667\\pi$
−0.5000000.866025i$-0.666667\\pi$
$510$00
$511$00
$512$1.00000i1.00000i
$513$00
$514$−1.00000+1.73205i−1.00000+1.73205i
$515$00
$516$00
$517$00
$518$00
$519$00
$520$00
$521$1.366030.366025i1.366030.366025i0.5000000.866025i$-0.333333\\pi$
0.866025+0.500000i$0.166667\\pi$
$522$−0.3660251.36603i−0.3660251.36603i
$523$00−0.5000000.866025i$-0.666667\\pi$
0.500000+0.866025i$0.333333\\pi$
$524$00
$525$00
$526$00
$527$00
$528$00
$529$−0.8660250.500000i−0.8660250.500000i
$530$00
$531$00
$532$00
$533$00
$534$00
$535$00
$536$00
$537$00
$538$−1.000001.00000i−1.000001.00000i
$539$00
$540$00
$541$1.36603+0.366025i1.36603+0.366025i0.8660250.500000i$-0.166667\\pi$
0.500000+0.866025i$0.333333\\pi$
$542$00
$543$00
$544$−0.866025+0.500000i−0.866025+0.500000i
$545$−2.00000−2.00000
$546$00
$547$000.7071070.707107i$-0.250000\\pi$
−0.707107+0.707107i$0.750000\\pi$
$548$00
$549$0.366025+1.36603i0.366025+1.36603i
$550$00
$551$00
$552$00
$553$00
$554$−1.000001.00000i−1.000001.00000i
$555$00
$556$00
$557$00−0.8660250.500000i$-0.833333\\pi$
0.866025+0.500000i$0.166667\\pi$
$558$00
$559$00
$560$00
$561$00
$562$00
$563$00−0.8660250.500000i$-0.833333\\pi$
0.866025+0.500000i$0.166667\\pi$
$564$00
$565$1.00000+1.73205i1.00000+1.73205i
$566$00
$567$00
$568$00
$569$00−0.5000000.866025i$-0.666667\\pi$
0.500000+0.866025i$0.333333\\pi$
$570$00
$571$000.9659260.258819i$-0.0833333\\pi$
−0.965926+0.258819i$0.916667\\pi$
$572$00
$573$00
$574$00
$575$00
$576$0.8660250.500000i0.8660250.500000i
$577$00−0.8660250.500000i$-0.833333\\pi$
0.866025+0.500000i$0.166667\\pi$
$578$0.866025+0.500000i0.866025+0.500000i
$579$00
$580$2.00000i2.00000i
$581$00
$582$00
$583$00
$584$1.366030.366025i1.366030.366025i
$585$00
$586$−1.73205+1.00000i−1.73205+1.00000i
$587$001.00000i$-0.5\\pi$
1.00000i$0.5\\pi$
$588$00
$589$00
$590$00
$591$00
$592$−0.3660251.36603i−0.3660251.36603i
$593$00−0.5000000.866025i$-0.666667\\pi$
0.500000+0.866025i$0.333333\\pi$
$594$00
$595$00
$596$−2.00000−2.00000
$597$00
$598$00
$599$000.5000000.866025i$-0.333333\\pi$
−0.500000+0.866025i$0.666667\\pi$
$600$00
$601$−1.000001.00000i−1.000001.00000i1.00000i$-0.5\\pi$
−1.00000$\\pi$
$602$00
$603$00
$604$00
$605$−1.36603+0.366025i−1.36603+0.366025i
$606$00
$607$00−0.9659260.258819i$-0.916667\\pi$
0.965926+0.258819i$0.0833333\\pi$
$608$00
$609$00
$610$2.00000i2.00000i
$611$00
$612$−0.8660250.500000i−0.8660250.500000i
$613$−1.00000+1.73205i−1.00000+1.73205i−0.500000+0.866025i$0.666667\\pi$
−0.500000+0.866025i$0.666667\\pi$
$614$00
$615$00
$616$00
$617$−1.00000+1.00000i−1.00000+1.00000i1.00000i$0.5\\pi$
−1.00000$\\pi$
$618$00
$619$000.9659260.258819i$-0.0833333\\pi$
−0.965926+0.258819i$0.916667\\pi$
$620$00
$621$00
$622$00
$623$00
$624$00
$625$−0.5000000.866025i−0.5000000.866025i
$626$−0.3660251.36603i−0.3660251.36603i
$627$00
$628$−1.000001.73205i−1.000001.73205i
$629$−1.00000+1.00000i−1.00000+1.00000i
$630$00
$631$001.00000i$-0.5\\pi$
1.00000i$0.5\\pi$
$632$00
$633$00
$634$0.366025+1.36603i0.366025+1.36603i
$635$00
$636$00
$637$00
$638$00
$639$00
$640$−1.36603+0.366025i−1.36603+0.366025i
$641$−0.3660251.36603i−0.3660251.36603i−0.8660250.500000i$-0.833333\\pi$
0.5000000.866025i$-0.333333\\pi$
$642$00
$643$000.7071070.707107i$-0.250000\\pi$
−0.707107+0.707107i$0.750000\\pi$
$644$00
$645$00
$646$00
$647$000.5000000.866025i$-0.333333\\pi$
−0.500000+0.866025i$0.666667\\pi$
$648$0.866025+0.500000i0.866025+0.500000i
$649$00
$650$00
$651$00
$652$00
$653$0.3660251.36603i0.3660251.36603i−0.5000000.866025i$-0.666667\\pi$
0.8660250.500000i$-0.166667\\pi$
$654$00
$655$00
$656$−0.366025+1.36603i−0.366025+1.36603i
$657$1.00000+1.00000i1.00000+1.00000i
$658$00
$659$001.00000$0$
−1.00000$\\pi$
$660$00
$661$000.5000000.866025i$-0.333333\\pi$
−0.500000+0.866025i$0.666667\\pi$
$662$00
$663$00
$664$00
$665$00
$666$1.000001.00000i1.000001.00000i
$667$00
$668$00
$669$00
$670$00
$671$00
$672$00
$673$−1.000001.00000i−1.000001.00000i1.00000i$-0.5\\pi$
−1.00000$\\pi$
$674$−0.366025+1.36603i−0.366025+1.36603i
$675$00
$676$−0.500000+0.866025i−0.500000+0.866025i
$677$1.36603+0.366025i1.36603+0.366025i0.8660250.500000i$-0.166667\\pi$
0.500000+0.866025i$0.333333\\pi$
$678$00
$679$00
$680$1.00000+1.00000i1.00000+1.00000i
$681$00
$682$00
$683$00−0.2588190.965926i$-0.583333\\pi$
0.258819+0.965926i$0.416667\\pi$
$684$00
$685$00
$686$00
$687$00
$688$00
$689$00
$690$00
$691$000.2588190.965926i$-0.416667\\pi$
−0.258819+0.965926i$0.583333\\pi$
$692$1.000001.00000i1.000001.00000i
$693$00
$694$00
$695$00
$696$00
$697$1.366030.366025i1.366030.366025i
$698$00
$699$00
$700$00
$701$001.00000i$-0.5\\pi$
1.00000i$0.5\\pi$
$702$00
$703$00
$704$00
$705$00
$706$2.00000i2.00000i
$707$00
$708$00
$709$−1.366030.366025i−1.366030.366025i−0.5000000.866025i$-0.666667\\pi$
−0.866025+0.500000i$0.833333\\pi$
$710$00
$711$00
$712$00
$713$00
$714$00
$715$00
$716$00
$717$00
$718$00
$719$00−0.9659260.258819i$-0.916667\\pi$
0.965926+0.258819i$0.0833333\\pi$
$720$−1.000001.00000i−1.000001.00000i
$721$00
$722$1.00000i1.00000i
$723$00
$724$1.366030.366025i1.366030.366025i
$725$1.366030.366025i1.366030.366025i
$726$00
$727$001.00000$0$
−1.00000$\\pi$
$728$00
$729$1.00000i1.00000i
$730$−1.000001.73205i−1.000001.73205i
$731$00
$732$00
$733$00−0.5000000.866025i$-0.666667\\pi$
0.500000+0.866025i$0.333333\\pi$
$734$00
$735$00
$736$00
$737$00
$738$−1.36603+0.366025i−1.36603+0.366025i
$739$00−0.8660250.500000i$-0.833333\\pi$
0.866025+0.500000i$0.166667\\pi$
$740$−1.73205+1.00000i−1.73205+1.00000i
$741$00
$742$00
$743$000.7071070.707107i$-0.250000\\pi$
−0.707107+0.707107i$0.750000\\pi$
$744$00
$745$0.732051+2.73205i0.732051+2.73205i
$746$00
$747$00
$748$00
$749$00
$750$00
$751$00−0.9659260.258819i$-0.916667\\pi$
0.965926+0.258819i$0.0833333\\pi$
$752$00
$753$00
$754$00
$755$00
$756$00
$757$2.00000i2.00000i1.00000i$0.5\\pi$
1.00000i$0.5\\pi$
$758$00
$759$00
$760$00
$761$000.8660250.500000i$-0.166667\\pi$
−0.866025+0.500000i$0.833333\\pi$
$762$00
$763$00
$764$00
$765$−0.366025+1.36603i−0.366025+1.36603i
$766$00
$767$00
$768$00
$769$001.00000i$-0.5\\pi$
1.00000i$0.5\\pi$
$770$00
$771$00
$772$−0.366025+1.36603i−0.366025+1.36603i
$773$−1.732051.00000i−1.732051.00000i−0.8660250.500000i$-0.833333\\pi$
−0.8660250.500000i$-0.833333\\pi$
$774$00
$775$00
$776$1.00000+1.00000i1.00000+1.00000i
$777$00
$778$2.000002.00000
$779$00
$780$00
$781$00
$782$00
$783$00
$784$00
$785$−2.00000+2.00000i−2.00000+2.00000i
$786$00
$787$00−0.2588190.965926i$-0.583333\\pi$
0.258819+0.965926i$0.416667\\pi$
$788$1.366030.366025i1.366030.366025i
$789$00
$790$00
$791$00
$792$00
$793$00
$794$0.366025+1.36603i0.366025+1.36603i
$795$00
$796$00
$797$001.00000$0$
−1.00000$\\pi$
$798$00
$799$00
$800$0.500000+0.866025i0.500000+0.866025i
$801$00
$802$0.366025+1.36603i0.366025+1.36603i
$803$00
$804$00
$805$00
$806$00
$807$00
$808$00
$809$1.366030.366025i1.366030.366025i0.5000000.866025i$-0.333333\\pi$
0.866025+0.500000i$0.166667\\pi$
$810$0.3660251.36603i0.3660251.36603i
$811$000.7071070.707107i$-0.250000\\pi$
−0.707107+0.707107i$0.750000\\pi$
$812$00
$813$00
$814$00
$815$00
$816$00
$817$00
$818$2.00000i2.00000i
$819$00
$820$2.000002.00000
$821$−1.366030.366025i−1.366030.366025i−0.5000000.866025i$-0.666667\\pi$
−0.866025+0.500000i$0.833333\\pi$
$822$00
$823$000.9659260.258819i$-0.0833333\\pi$
−0.965926+0.258819i$0.916667\\pi$
$824$00
$825$00
$826$00
$827$00−0.7071070.707107i$-0.750000\\pi$
0.707107+0.707107i$0.250000\\pi$
$828$00
$829$1.000001.73205i1.000001.73205i0.5000000.866025i$-0.333333\\pi$
0.5000000.866025i$-0.333333\\pi$
$830$00
$831$00
$832$00
$833$00
$834$00
$835$00
$836$00
$837$00
$838$00
$839$00−0.7071070.707107i$-0.750000\\pi$
0.707107+0.707107i$0.250000\\pi$
$840$00
$841$1.00000i1.00000i
$842$00
$843$00
$844$00
$845$1.36603+0.366025i1.36603+0.366025i
$846$00
$847$00
$848$00
$849$00
$850$0.5000000.866025i0.5000000.866025i
$851$00
$852$00
$853$1.000001.00000i1.000001.00000i1.00000i$-0.5\\pi$
1.00000$0$
$854$00
$855$00
$856$00
$857$1.366030.366025i1.366030.366025i0.5000000.866025i$-0.333333\\pi$
0.866025+0.500000i$0.166667\\pi$
$858$00
$859$000.8660250.500000i$-0.166667\\pi$
−0.866025+0.500000i$0.833333\\pi$
$860$00
$861$00
$862$00
$863$00−0.5000000.866025i$-0.666667\\pi$
0.500000+0.866025i$0.333333\\pi$
$864$00
$865$−1.732051.00000i−1.732051.00000i
$866$−1.000001.73205i−1.000001.73205i
$867$00
$868$00
$869$00
$870$00
$871$00
$872$0.366025+1.36603i0.366025+1.36603i
$873$−0.366025+1.36603i−0.366025+1.36603i
$874$00
$875$00
$876$00
$877$−0.366025+1.36603i−0.366025+1.36603i0.500000+0.866025i$0.333333\\pi$
−0.866025+0.500000i$0.833333\\pi$
$878$00
$879$00
$880$00
$881$−1.00000+1.00000i−1.00000+1.00000i1.00000i$0.5\\pi$
−1.00000$\\pi$
$882$00
$883$001.00000$0$
−1.00000$\\pi$
$884$00
$885$00
$886$00
$887$00−0.9659260.258819i$-0.916667\\pi$
0.965926+0.258819i$0.0833333\\pi$
$888$00
$889$00
$890$00
$891$00
$892$00
$893$00
$894$00
$895$00
$896$00
$897$00
$898$1.36603+0.366025i1.36603+0.366025i
$899$00
$900$−0.500000+0.866025i−0.500000+0.866025i
$901$00
$902$00
$903$00
$904$1.000001.00000i1.000001.00000i
$905$−1.000001.73205i−1.000001.73205i
$906$00
$907$000.9659260.258819i$-0.0833333\\pi$
−0.965926+0.258819i$0.916667\\pi$
$908$00
$909$00
$910$00
$911$00−0.7071070.707107i$-0.750000\\pi$
0.707107+0.707107i$0.250000\\pi$
$912$00
$913$00
$914$1.000001.73205i1.000001.73205i
$915$00
$916$2.00000i2.00000i
$917$00
$918$00
$919$00−0.5000000.866025i$-0.666667\\pi$
0.500000+0.866025i$0.333333\\pi$
$920$00
$921$00
$922$00
$923$00
$924$00
$925$1.00000+1.00000i1.00000+1.00000i
$926$00
$927$00
$928$1.366030.366025i1.366030.366025i
$929$−0.366025+1.36603i−0.366025+1.36603i0.500000+0.866025i$0.333333\\pi$
−0.866025+0.500000i$0.833333\\pi$
$930$00
$931$00
$932$1.000001.00000i1.000001.00000i
$933$00
$934$00
$935$00
$936$00
$937$001.00000$0$
−1.00000$\\pi$
$938$00
$939$00
$940$00
$941$1.366030.366025i1.366030.366025i0.5000000.866025i$-0.333333\\pi$
0.866025+0.500000i$0.166667\\pi$
$942$00
$943$00
$944$00
$945$00
$946$00
$947$00−0.9659260.258819i$-0.916667\\pi$
0.965926+0.258819i$0.0833333\\pi$
$948$00
$949$00
$950$00
$951$00
$952$00
$953$001.00000i$-0.5\\pi$
1.00000i$0.5\\pi$
$954$00
$955$00
$956$00
$957$00
$958$00
$959$00
$960$00
$961$−0.866025+0.500000i−0.866025+0.500000i
$962$00
$963$00
$964$−1.366030.366025i−1.366030.366025i
$965$2.000002.00000
$966$00
$967$001.00000i$-0.5\\pi$
1.00000i$0.5\\pi$
$968$0.500000+0.866025i0.500000+0.866025i
$969$00
$970$1.000001.73205i1.000001.73205i
$971$000.8660250.500000i$-0.166667\\pi$
−0.866025+0.500000i$0.833333\\pi$
$972$00
$973$00
$974$00
$975$00
$976$−1.36603+0.366025i−1.36603+0.366025i
$977$000.5000000.866025i$-0.333333\\pi$
−0.500000+0.866025i$0.666667\\pi$
$978$00
$979$00
$980$00
$981$−1.00000+1.00000i−1.00000+1.00000i
$982$00
$983$00−0.2588190.965926i$-0.583333\\pi$
0.258819+0.965926i$0.416667\\pi$
$984$00
$985$−1.000001.73205i−1.000001.73205i
$986$−1.000001.00000i−1.000001.00000i
$987$00
$988$00
$989$00
$990$00
$991$00−0.2588190.965926i$-0.583333\\pi$
0.258819+0.965926i$0.416667\\pi$
$992$00
$993$00
$994$00
$995$00
$996$00
$997$1.366030.366025i1.366030.366025i0.5000000.866025i$-0.333333\\pi$
0.866025+0.500000i$0.166667\\pi$
$998$00
$999$00
", "is_complex": true, "table_nest_level": "1"}}, {"type": "paragraph", "raw_content": "
\n (See a_n instead)\n \n (See a_n instead)\n \n (See a_n instead)\n \n (See only a_p)\n \n (See only a_p)\n \n (See only a_p)\n
", "content": [{"c": "(See", "t": "text"}, {"c": "a_n", "t": "equation-inline"}, {"c": "instead)(See", "t": "text"}, {"c": "a_n", "t": "equation-inline"}, {"c": "instead)(See", "t": "text"}, {"c": "a_n", "t": "equation-inline"}, {"c": "instead)(See only", "t": "text"}, {"c": "a_p", "t": "equation-inline"}, {"c": ")(See only", "t": "text"}, {"c": "a_p", "t": "equation-inline"}, {"c": ")(See only", "t": "text"}, {"c": "a_p", "t": "equation-inline"}, {"c": ")", "t": "text"}]}, {"type": "complex_table", "raw_content": "
       By twisting character
CharParityOrdTypeTwistMinDim
1.1even1trivial3332.1.bc.b.2027.14
4.3odd2CM3332.1.bc.b.2027.14
7.2even3inner3332.1.bc.b.667.14
7.3odd668.1.f.a.55.1yes2
7.4even33332.1.m.b.2843.12
7.5odd63332.1.bc.c.667.14
7.6odd23332.1.bc.c.2027.14
17.13even4inner3332.1.bc.b.2223.14
21.17even6612.1.l.a.55.12
28.3even668.1.f.a.55.1yes2
28.11odd63332.1.m.b.2843.12
28.19even63332.1.bc.c.667.14
28.23odd6inner3332.1.bc.b.667.14
28.27even23332.1.bc.c.2027.14
35.3even121700.1.n.a.599.12
35.17even121700.1.n.b.599.12
35.24odd61700.1.p.a.1551.12
56.3even61088.1.p.a.191.12
56.45odd61088.1.p.a.191.12
68.47odd4inner3332.1.bc.b.2223.14
84.59odd6612.1.l.a.55.12
119.3even481156.1.g.b.155.18
119.10even481156.1.g.b.179.18
119.13odd43332.1.bc.c.2223.14
119.24even481156.1.g.b.179.28
119.30even12inner3332.1.bc.b.863.14
119.31even481156.1.g.b.155.28
119.38odd121156.1.f.b.251.12
119.45even481156.1.g.b.399.18
119.47odd123332.1.bc.c.863.14
119.59odd241156.1.c.b.579.12
119.66odd241156.1.d.a.1155.22
119.73even481156.1.g.b.423.28
119.80even481156.1.g.b.423.18
119.81even123332.1.m.b.3039.12
119.87odd241156.1.d.a.1155.12
119.94odd241156.1.c.b.579.22
119.101odd61156.1.f.b.327.12
119.108even481156.1.g.b.399.28
119.115odd1268.1.f.a.47.1&check;2
140.3odd121700.1.n.a.599.12
140.59even61700.1.p.a.1551.12
140.87odd121700.1.n.b.599.12
357.353even12612.1.l.a.523.12
476.3odd481156.1.g.b.155.18
476.31odd481156.1.g.b.155.28
476.47even123332.1.bc.c.863.14
476.59even241156.1.c.b.579.12
476.87even241156.1.d.a.1155.12
476.115even1268.1.f.a.47.1&check;2
476.143odd481156.1.g.b.179.28
476.199odd481156.1.g.b.423.18
476.227odd481156.1.g.b.399.28
476.251even43332.1.bc.c.2223.14
476.283odd481156.1.g.b.399.18
476.311odd481156.1.g.b.423.28
476.319odd123332.1.m.b.3039.12
476.339even61156.1.f.b.327.12
476.367odd481156.1.g.b.179.18
476.387odd12inner3332.1.bc.b.863.14
476.395even121156.1.f.b.251.12
476.423even241156.1.d.a.1155.22
476.451even241156.1.c.b.579.22
595.234odd121700.1.p.a.251.12
595.353even121700.1.n.b.999.12
595.472even121700.1.n.a.999.12
952.115even121088.1.p.a.319.12
952.829odd121088.1.p.a.319.12
1428.1067odd12612.1.l.a.523.12
2380.1067odd121700.1.n.a.999.12
2380.1543odd121700.1.n.b.999.12
2380.2019even121700.1.p.a.251.12
", "content": {"html": "
       By twisting character
CharParityOrdTypeTwistMinDim
1.1even1trivial3332.1.bc.b.2027.14
4.3odd2CM3332.1.bc.b.2027.14
7.2even3inner3332.1.bc.b.667.14
7.3odd668.1.f.a.55.1yes2
7.4even33332.1.m.b.2843.12
7.5odd63332.1.bc.c.667.14
7.6odd23332.1.bc.c.2027.14
17.13even4inner3332.1.bc.b.2223.14
21.17even6612.1.l.a.55.12
28.3even668.1.f.a.55.1yes2
28.11odd63332.1.m.b.2843.12
28.19even63332.1.bc.c.667.14
28.23odd6inner3332.1.bc.b.667.14
28.27even23332.1.bc.c.2027.14
35.3even121700.1.n.a.599.12
35.17even121700.1.n.b.599.12
35.24odd61700.1.p.a.1551.12
56.3even61088.1.p.a.191.12
56.45odd61088.1.p.a.191.12
68.47odd4inner3332.1.bc.b.2223.14
84.59odd6612.1.l.a.55.12
119.3even481156.1.g.b.155.18
119.10even481156.1.g.b.179.18
119.13odd43332.1.bc.c.2223.14
119.24even481156.1.g.b.179.28
119.30even12inner3332.1.bc.b.863.14
119.31even481156.1.g.b.155.28
119.38odd121156.1.f.b.251.12
119.45even481156.1.g.b.399.18
119.47odd123332.1.bc.c.863.14
119.59odd241156.1.c.b.579.12
119.66odd241156.1.d.a.1155.22
119.73even481156.1.g.b.423.28
119.80even481156.1.g.b.423.18
119.81even123332.1.m.b.3039.12
119.87odd241156.1.d.a.1155.12
119.94odd241156.1.c.b.579.22
119.101odd61156.1.f.b.327.12
119.108even481156.1.g.b.399.28
119.115odd1268.1.f.a.47.12
140.3odd121700.1.n.a.599.12
140.59even61700.1.p.a.1551.12
140.87odd121700.1.n.b.599.12
357.353even12612.1.l.a.523.12
476.3odd481156.1.g.b.155.18
476.31odd481156.1.g.b.155.28
476.47even123332.1.bc.c.863.14
476.59even241156.1.c.b.579.12
476.87even241156.1.d.a.1155.12
476.115even1268.1.f.a.47.12
476.143odd481156.1.g.b.179.28
476.199odd481156.1.g.b.423.18
476.227odd481156.1.g.b.399.28
476.251even43332.1.bc.c.2223.14
476.283odd481156.1.g.b.399.18
476.311odd481156.1.g.b.423.28
476.319odd123332.1.m.b.3039.12
476.339even61156.1.f.b.327.12
476.367odd481156.1.g.b.179.18
476.387odd12inner3332.1.bc.b.863.14
476.395even121156.1.f.b.251.12
476.423even241156.1.d.a.1155.22
476.451even241156.1.c.b.579.22
595.234odd121700.1.p.a.251.12
595.353even121700.1.n.b.999.12
595.472even121700.1.n.a.999.12
952.115even121088.1.p.a.319.12
952.829odd121088.1.p.a.319.12
1428.1067odd12612.1.l.a.523.12
2380.1067odd121700.1.n.a.999.12
2380.1543odd121700.1.n.b.999.12
2380.2019even121700.1.p.a.251.12
", "is_complex": true, "table_nest_level": "1"}}, {"type": "complex_table", "raw_content": "
        By twisted newform
TwistMinDimCharParityOrdType
68.1.f.a.47.1&check;2119.115odd12
68.1.f.a.47.1&check;2476.115even12
68.1.f.a.55.1yes27.3odd6
68.1.f.a.55.1yes228.3even6
612.1.l.a.55.1221.17even6
612.1.l.a.55.1284.59odd6
612.1.l.a.523.12357.353even12
612.1.l.a.523.121428.1067odd12
1088.1.p.a.191.1256.3even6
1088.1.p.a.191.1256.45odd6
1088.1.p.a.319.12952.115even12
1088.1.p.a.319.12952.829odd12
1156.1.c.b.579.12119.59odd24
1156.1.c.b.579.12476.59even24
1156.1.c.b.579.22119.94odd24
1156.1.c.b.579.22476.451even24
1156.1.d.a.1155.12119.87odd24
1156.1.d.a.1155.12476.87even24
1156.1.d.a.1155.22119.66odd24
1156.1.d.a.1155.22476.423even24
1156.1.f.b.251.12119.38odd12
1156.1.f.b.251.12476.395even12
1156.1.f.b.327.12119.101odd6
1156.1.f.b.327.12476.339even6
1156.1.g.b.155.18119.3even48
1156.1.g.b.155.18476.3odd48
1156.1.g.b.155.28119.31even48
1156.1.g.b.155.28476.31odd48
1156.1.g.b.179.18119.10even48
1156.1.g.b.179.18476.367odd48
1156.1.g.b.179.28119.24even48
1156.1.g.b.179.28476.143odd48
1156.1.g.b.399.18119.45even48
1156.1.g.b.399.18476.283odd48
1156.1.g.b.399.28119.108even48
1156.1.g.b.399.28476.227odd48
1156.1.g.b.423.18119.80even48
1156.1.g.b.423.18476.199odd48
1156.1.g.b.423.28119.73even48
1156.1.g.b.423.28476.311odd48
1700.1.n.a.599.1235.3even12
1700.1.n.a.599.12140.3odd12
1700.1.n.a.999.12595.472even12
1700.1.n.a.999.122380.1067odd12
1700.1.n.b.599.1235.17even12
1700.1.n.b.599.12140.87odd12
1700.1.n.b.999.12595.353even12
1700.1.n.b.999.122380.1543odd12
1700.1.p.a.251.12595.234odd12
1700.1.p.a.251.122380.2019even12
1700.1.p.a.1551.1235.24odd6
1700.1.p.a.1551.12140.59even6
3332.1.m.b.2843.127.4even3
3332.1.m.b.2843.1228.11odd6
3332.1.m.b.3039.12119.81even12
3332.1.m.b.3039.12476.319odd12
3332.1.bc.b.667.147.2even3inner
3332.1.bc.b.667.1428.23odd6inner
3332.1.bc.b.863.14119.30even12inner
3332.1.bc.b.863.14476.387odd12inner
3332.1.bc.b.2027.141.1even1trivial
3332.1.bc.b.2027.144.3odd2CM
3332.1.bc.b.2223.1417.13even4inner
3332.1.bc.b.2223.1468.47odd4inner
3332.1.bc.c.667.147.5odd6
3332.1.bc.c.667.1428.19even6
3332.1.bc.c.863.14119.47odd12
3332.1.bc.c.863.14476.47even12
3332.1.bc.c.2027.147.6odd2
3332.1.bc.c.2027.1428.27even2
3332.1.bc.c.2223.14119.13odd4
3332.1.bc.c.2223.14476.251even4
", "content": {"html": "
        By twisted newform
TwistMinDimCharParityOrdType
68.1.f.a.47.12119.115odd12
68.1.f.a.47.12476.115even12
68.1.f.a.55.1yes27.3odd6
68.1.f.a.55.1yes228.3even6
612.1.l.a.55.1221.17even6
612.1.l.a.55.1284.59odd6
612.1.l.a.523.12357.353even12
612.1.l.a.523.121428.1067odd12
1088.1.p.a.191.1256.3even6
1088.1.p.a.191.1256.45odd6
1088.1.p.a.319.12952.115even12
1088.1.p.a.319.12952.829odd12
1156.1.c.b.579.12119.59odd24
1156.1.c.b.579.12476.59even24
1156.1.c.b.579.22119.94odd24
1156.1.c.b.579.22476.451even24
1156.1.d.a.1155.12119.87odd24
1156.1.d.a.1155.12476.87even24
1156.1.d.a.1155.22119.66odd24
1156.1.d.a.1155.22476.423even24
1156.1.f.b.251.12119.38odd12
1156.1.f.b.251.12476.395even12
1156.1.f.b.327.12119.101odd6
1156.1.f.b.327.12476.339even6
1156.1.g.b.155.18119.3even48
1156.1.g.b.155.18476.3odd48
1156.1.g.b.155.28119.31even48
1156.1.g.b.155.28476.31odd48
1156.1.g.b.179.18119.10even48
1156.1.g.b.179.18476.367odd48
1156.1.g.b.179.28119.24even48
1156.1.g.b.179.28476.143odd48
1156.1.g.b.399.18119.45even48
1156.1.g.b.399.18476.283odd48
1156.1.g.b.399.28119.108even48
1156.1.g.b.399.28476.227odd48
1156.1.g.b.423.18119.80even48
1156.1.g.b.423.18476.199odd48
1156.1.g.b.423.28119.73even48
1156.1.g.b.423.28476.311odd48
1700.1.n.a.599.1235.3even12
1700.1.n.a.599.12140.3odd12
1700.1.n.a.999.12595.472even12
1700.1.n.a.999.122380.1067odd12
1700.1.n.b.599.1235.17even12
1700.1.n.b.599.12140.87odd12
1700.1.n.b.999.12595.353even12
1700.1.n.b.999.122380.1543odd12
1700.1.p.a.251.12595.234odd12
1700.1.p.a.251.122380.2019even12
1700.1.p.a.1551.1235.24odd6
1700.1.p.a.1551.12140.59even6
3332.1.m.b.2843.127.4even3
3332.1.m.b.2843.1228.11odd6
3332.1.m.b.3039.12119.81even12
3332.1.m.b.3039.12476.319odd12
3332.1.bc.b.667.147.2even3inner
3332.1.bc.b.667.1428.23odd6inner
3332.1.bc.b.863.14119.30even12inner
3332.1.bc.b.863.14476.387odd12inner
3332.1.bc.b.2027.141.1even1trivial
3332.1.bc.b.2027.144.3odd2CM
3332.1.bc.b.2223.1417.13even4inner
3332.1.bc.b.2223.1468.47odd4inner
3332.1.bc.c.667.147.5odd6
3332.1.bc.c.667.1428.19even6
3332.1.bc.c.863.14119.47odd12
3332.1.bc.c.863.14476.47even12
3332.1.bc.c.2027.147.6odd2
3332.1.bc.c.2027.1428.27even2
3332.1.bc.c.2223.14119.13odd4
3332.1.bc.c.2223.14476.251even4
", "is_complex": true, "table_nest_level": "1"}}]], "html": "\n\n\n \n \n \n \n LMFDB - Embedded newform 3332.1.bc.b.2027.1 \n \n\n \n \n \n \n \n\n \n \n\n\n\n\n \n\n \n \n\n \n \n\n\n \n \n \n \n \n \n\n\n\n\n\n \n \n\n
\n
\n \n
\n
\n
\n
\n \n → Modular forms\n → Classical\n → Level 3332\n → Weight 1\n → Character orbit bc\n → Newform orbit b\n → Embedding 2027.1\n
\n
\n \n
\n Citation\n ·\n Feedback\n ·\n Hide Menu\n \n
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\n
Embedded newform 3332.1.bc.b.2027.1
\n\n
\n
\n\n
\n

Introduction

\n\n\n\n \n \n \n
OverviewRandom
UniverseKnowledge
\n\n\n\n

L-functions

\n\n\n\n \n \n \n
RationalAll
\n\n\n\n

Modular forms

\n\n\n\n \n \n \n
ClassicalMaass
HilbertBianchi
\n\n\n\n

Varieties

\n\n\n\n \n \n \n
Elliptic curves over $\\Q$
Elliptic curves over $\\Q(\\alpha)$
Genus 2 curves over $\\Q$
Higher genus families
Abelian varieties over $\\F_{q}$
\n\n\n\n

Fields

\n\n\n\n \n \n \n
Number fields
$p$-adic fields
\n\n\n\n

Representations

\n\n\n\n \n \n \n
Dirichlet characters
Artin representations
\n\n\n\n

Groups

\n\n\n\n \n \n \n
Galois groups
Sato-Tate groups
\n\n\n\n

Database

\n\n\n\n\n
\n\n\n\n
\n
\n

Properties

\n
\n \n
Label\n 3332.1.bc.b.2027.1
\n
Level\n $3332$
Weight\n $1$
Character\n 3332.2027
Analytic conductor\n $1.663$
Analytic rank\n $0$
Dimension\n $4$
Projective image\n $D_{4}$
CM discriminant\n -4
Inner twists\n $8$
\n
\n\n\n\n

Related objects

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\n\n\n\n

Downloads

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Learn more

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\n Show commands:\n Magma\n / PariGP\n / SageMath\n
\n\n\n\n\n

Newspace parameters

\n\n
comment: Compute space of new eigenforms
 
\n
[N,k,chi] = [3332,1,Mod(667,3332)]
 
mf = mfinit([N,k,chi],0)
 
lf = mfeigenbasis(mf)
 
\n
from sage.modular.dirichlet import DirichletCharacter
 
H = DirichletGroup(3332, base_ring=CyclotomicField(12))
 
chi = DirichletCharacter(H, H._module([6, 4, 9]))
 
N = Newforms(chi, 1, names="a")
 
\n
//Please install CHIMP (https://github.com/edgarcosta/CHIMP) if you want to run this code
 
chi := DirichletCharacter("3332.667");
 
S:= CuspForms(chi, 1);
 
N := Newforms(S);
 
\n\n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n
Level: \\( N \\) \\(=\\)\\( 3332 = 2^{2} \\cdot 7^{2} \\cdot 17 \\)
Weight: \\( k \\) \\(=\\)\\( 1 \\)
Character orbit: \\([\\chi]\\) \\(=\\) 3332.bc (of order \\(12\\), degree \\(4\\), not minimal)
\n\n

Newform invariants

\n\n
comment: select newform
 
\n
sage: f = N[0] # Warning: the index may be different
 
\n
gp: f = lf[1] \\\\ Warning: the index may be different
 
\n\n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\t\n \n \t\n \t\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n
Self dual: no
Analytic conductor: \\(1.66288462209\\)
Analytic rank: \\(0\\)
Dimension: \\(4\\)
Coefficient field: \\(\\Q(\\zeta_{12})\\)
\n
comment: defining polynomial
 
\n
gp: f.mod \\\\ as an extension of the character field
 
\n\n
Defining polynomial: \n\n \\( x^{4} - x^{2} + 1 \\)\n \n\n \n \"Copy\n \n \n \"Toggle\n \n
Coefficient ring: \\(\\Z[a_1, a_2]\\)
Coefficient ring index: \\( 1 \\)
Twist minimal: no (minimal twist has level 68)
Projective image:\\(D_{4}\\)
Projective field:Galois closure of 4.2.19652.1
Artin image:$C_4\\wr C_2\\times C_6$
Artin field:Galois closure of \\(\\mathbb{Q}[x]/(x^{48} - \\cdots)\\)
\n\n\n

Embedding invariants

\n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n
Embedding label 2027.1
Root\\(0.866025 - 0.500000i\\) of defining polynomial
Character\\(\\chi\\)\\(=\\)3332.2027
Dual form 3332.1.bc.b.863.1
\n\n\n

$q$-expansion

\n
\n
comment: q-expansion
 
\n
sage: f.q_expansion() # note that sage often uses an isomorphic number field
 
\n
gp: mfcoefs(f, 20)
 
\n\n
\n \n \n \n \n \n \n \n \n \n \n \n
\\(f(q)\\)\\(=\\)\\(q+(-0.866025 + 0.500000i) q^{2} +(0.500000 - 0.866025i) q^{4} +(-1.36603 - 0.366025i) q^{5} +1.00000i q^{8} +(-0.866025 + 0.500000i) q^{9} +(1.36603 - 0.366025i) q^{10} +(-0.500000 - 0.866025i) q^{16} +(-0.500000 + 0.866025i) q^{17} +(0.500000 - 0.866025i) q^{18} +(-1.00000 + 1.00000i) q^{20} +(0.866025 + 0.500000i) q^{25} +(1.00000 - 1.00000i) q^{29} +(0.866025 + 0.500000i) q^{32} -1.00000i q^{34} +1.00000i q^{36} +(1.36603 + 0.366025i) q^{37} +(0.366025 - 1.36603i) q^{40} +(-1.00000 - 1.00000i) q^{41} +(1.36603 - 0.366025i) q^{45} -1.00000 q^{50} +(-0.366025 + 1.36603i) q^{58} +(0.366025 - 1.36603i) q^{61} -1.00000 q^{64} +(0.500000 + 0.866025i) q^{68} +(-0.500000 - 0.866025i) q^{72} +(-0.366025 - 1.36603i) q^{73} +(-1.36603 + 0.366025i) q^{74} +(0.366025 + 1.36603i) q^{80} +(0.500000 - 0.866025i) q^{81} +(1.36603 + 0.366025i) q^{82} +(1.00000 - 1.00000i) q^{85} +(-1.00000 + 1.00000i) q^{90} +(1.00000 - 1.00000i) q^{97} +O(q^{100})\\)
\\(\\operatorname{Tr}(f)(q)\\)\\(=\\)\n\n \\( 4 q + 2 q^{4} - 2 q^{5} + 2 q^{10} - 2 q^{16} - 2 q^{17} + 2 q^{18} - 4 q^{20} + 4 q^{29} + 2 q^{37} - 2 q^{40} - 4 q^{41} + 2 q^{45} - 4 q^{50} + 2 q^{58} - 2 q^{61} - 4 q^{64} + 2 q^{68} - 2 q^{72} + 2 q^{73}+ \\cdots + 4 q^{97}+O(q^{100}) \\)\n \n\n \n \"Copy\n \n \n \"Toggle\n \n
\n
\n\n
\n\n\n

Character values

\n

We give the values of \\(\\chi\\) on generators for \\(\\left(\\mathbb{Z}/3332\\mathbb{Z}\\right)^\\times\\).

\n\n \n \n \n \n \n \n \n \n \n \n \n \n
\\(n\\)\\(785\\)\\(885\\)\\(1667\\)
\\(\\chi(n)\\)\\(e\\left(\\frac{3}{4}\\right)\\)\\(e\\left(\\frac{2}{3}\\right)\\)\\(-1\\)
\n\n\n

Coefficient data

\n\n

For each \\(n\\) we display the coefficients of the \\(q\\)-expansion \\(a_n\\), the\nSatake parameters \\(\\alpha_p\\),\nand the Satake angles \\(\\theta_p = \\textrm{Arg}(\\alpha_p)\\).

\n\n\n\n\n

\n
\n \n Display \\(a_p\\) with \\(p\\) up to:\n 50\n 250\n 1000\n \n\n \n (See \\(a_n\\) instead)\n \n\n \n (See \\(a_n\\) instead)\n \n\n \n (See \\(a_n\\) instead)\n \n \n Display \\(a_n\\) with \\(n\\) up to:\n 50\n 250\n 1000\n \n\n \n (See only \\(a_p\\))\n \n\n \n (See only \\(a_p\\))\n \n\n \n (See only \\(a_p\\))\n \n
\n\n\n
\n \n \n \n \n \n \n
Significant digits:
\n
\n\n
\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n 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\n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n \n \n \n \n
\n \\(n\\)\n \n \\(a_n\\)\n \n \\(a_n / n^{(k-1)/2}\\)\n \n \\( \\alpha_n \\)\n \n \\( \\theta_n \\)\n
\n \\(p\\)\n \n \\(a_p\\)\n \n \\(a_p / p^{(k-1)/2}\\)\n \n \\( \\alpha_p\\)\n \n \\( \\theta_p \\)\n
\n \\(2\\)\n \n −0.866025\n \n +\n \n 0.500000i\n \n −0.866025\n \n +\n \n 0.500000i\n \n\n \n\n \n\n \n\n
\n\n \n\n \n\n \n\n
\n \\(3\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.258819\n \n −\n \n 0.965926i\n \n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \n \\(0.416667\\pi\\)\n
\n \\(4\\)\n \n 0.500000\n \n −\n \n 0.866025i\n \n 0.500000\n \n −\n \n 0.866025i\n
\n \\(5\\)\n \n −1.36603\n \n −\n \n 0.366025i\n \n −1.36603\n \n −\n \n 0.366025i\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(6\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(7\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n\n \n\n \n\n
\n\n \n\n \n\n \n\n
\n \\(8\\)\n \n\n \n\n \n 1.00000i\n \n\n \n\n \n 1.00000i\n
\n \\(9\\)\n \n −0.866025\n \n +\n \n 0.500000i\n \n −0.866025\n \n +\n \n 0.500000i\n
\n \\(10\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n
\n \\(11\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.965926\n \n −\n \n 0.258819i\n \n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \n \\(0.916667\\pi\\)\n
\n \\(12\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(13\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(14\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(15\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(16\\)\n \n −0.500000\n \n −\n \n 0.866025i\n \n −0.500000\n \n −\n \n 0.866025i\n
\n \\(17\\)\n \n −0.500000\n \n +\n \n 0.866025i\n \n −0.500000\n \n +\n \n 0.866025i\n \n\n \n\n \n\n \n\n
\n\n \n\n \n\n \n\n
\n \\(18\\)\n \n 0.500000\n \n −\n \n 0.866025i\n \n 0.500000\n \n −\n \n 0.866025i\n
\n \\(19\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(20\\)\n \n −1.00000\n \n +\n \n 1.00000i\n \n −1.00000\n \n +\n \n 1.00000i\n
\n \\(21\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(22\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(23\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.258819\n \n −\n \n 0.965926i\n \n \\(-0.416667\\pi\\)\n
\n −0.258819\n \n +\n \n 0.965926i\n \n \\(0.583333\\pi\\)\n
\n \\(24\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(25\\)\n \n 0.866025\n \n +\n \n 0.500000i\n \n 0.866025\n \n +\n \n 0.500000i\n
\n \\(26\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(27\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(28\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(29\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n \\(30\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(31\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.258819\n \n −\n \n 0.965926i\n \n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \n \\(0.416667\\pi\\)\n
\n \\(32\\)\n \n 0.866025\n \n +\n \n 0.500000i\n \n 0.866025\n \n +\n \n 0.500000i\n
\n \\(33\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(34\\)\n \n\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n
\n \\(35\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(36\\)\n \n\n \n\n \n 1.00000i\n \n\n \n\n \n 1.00000i\n
\n \\(37\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(38\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(39\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(40\\)\n \n 0.366025\n \n −\n \n 1.36603i\n \n 0.366025\n \n −\n \n 1.36603i\n
\n \\(41\\)\n \n −1.00000\n \n −\n \n 1.00000i\n \n −1.00000\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(42\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(43\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(44\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(45\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n
\n \\(46\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(47\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(48\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(49\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(50\\)\n \n −1.00000\n \n\n \n\n \n −1.00000\n \n\n \n\n
\n \\(51\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(52\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(53\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(54\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(55\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(56\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(57\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(58\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n
\n \\(59\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(60\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(61\\)\n \n 0.366025\n \n −\n \n 1.36603i\n \n 0.366025\n \n −\n \n 1.36603i\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n \\(62\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(63\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(64\\)\n \n −1.00000\n \n\n \n\n \n −1.00000\n \n\n \n\n
\n \\(65\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(66\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(67\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(68\\)\n \n 0.500000\n \n +\n \n 0.866025i\n \n 0.500000\n \n +\n \n 0.866025i\n
\n \\(69\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(70\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(71\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.707107\n \n −\n \n 0.707107i\n \n \\(-0.250000\\pi\\)\n
\n −0.707107\n \n +\n \n 0.707107i\n \n \\(0.750000\\pi\\)\n
\n \\(72\\)\n \n −0.500000\n \n −\n \n 0.866025i\n \n −0.500000\n \n −\n \n 0.866025i\n
\n \\(73\\)\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n \\(74\\)\n \n −1.36603\n \n +\n \n 0.366025i\n \n −1.36603\n \n +\n \n 0.366025i\n
\n \\(75\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(76\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(77\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(78\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(79\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.258819\n \n −\n \n 0.965926i\n \n \\(-0.416667\\pi\\)\n
\n −0.258819\n \n +\n \n 0.965926i\n \n \\(0.583333\\pi\\)\n
\n \\(80\\)\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.366025\n \n +\n \n 1.36603i\n
\n \\(81\\)\n \n 0.500000\n \n −\n \n 0.866025i\n \n 0.500000\n \n −\n \n 0.866025i\n
\n \\(82\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n
\n \\(83\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(84\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(85\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n
\n \\(86\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(87\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(88\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(89\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(90\\)\n \n −1.00000\n \n +\n \n 1.00000i\n \n −1.00000\n \n +\n \n 1.00000i\n
\n \\(91\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(92\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(93\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(94\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(95\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(96\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(97\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n \\(98\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(99\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(100\\)\n \n 0.866025\n \n −\n \n 0.500000i\n \n 0.866025\n \n −\n \n 0.500000i\n
\n \\(101\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(102\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(103\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(104\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(105\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(106\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(107\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.965926\n \n −\n \n 0.258819i\n \n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \n \\(0.0833333\\pi\\)\n
\n \\(108\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(109\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(110\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(111\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(112\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(113\\)\n \n −1.00000\n \n −\n \n 1.00000i\n \n −1.00000\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(114\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(115\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(116\\)\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.366025\n \n −\n \n 1.36603i\n
\n \\(117\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(118\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(119\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(120\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(121\\)\n \n 0.866025\n \n −\n \n 0.500000i\n \n 0.866025\n \n −\n \n 0.500000i\n
\n \\(122\\)\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.366025\n \n +\n \n 1.36603i\n
\n \\(123\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(124\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(125\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(126\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(127\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(128\\)\n \n 0.866025\n \n −\n \n 0.500000i\n \n 0.866025\n \n −\n \n 0.500000i\n
\n \\(129\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(130\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(131\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.965926\n \n −\n \n 0.258819i\n \n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \n \\(0.0833333\\pi\\)\n
\n \\(132\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(133\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(134\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(135\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(136\\)\n \n −0.866025\n \n −\n \n 0.500000i\n \n −0.866025\n \n −\n \n 0.500000i\n
\n \\(137\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(138\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(139\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.707107\n \n −\n \n 0.707107i\n \n \\(-0.250000\\pi\\)\n
\n −0.707107\n \n +\n \n 0.707107i\n \n \\(0.750000\\pi\\)\n
\n \\(140\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(141\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(142\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(143\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(144\\)\n \n 0.866025\n \n +\n \n 0.500000i\n \n 0.866025\n \n +\n \n 0.500000i\n
\n \\(145\\)\n \n −1.73205\n \n +\n \n 1.00000i\n \n −1.73205\n \n +\n \n 1.00000i\n
\n \\(146\\)\n \n 1.00000\n \n +\n \n 1.00000i\n \n 1.00000\n \n +\n \n 1.00000i\n
\n \\(147\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(148\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n
\n \\(149\\)\n \n −1.00000\n \n −\n \n 1.73205i\n \n −1.00000\n \n −\n \n 1.73205i\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n \\(150\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(151\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(152\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(153\\)\n \n\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n
\n \\(154\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(155\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(156\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(157\\)\n \n 1.00000\n \n −\n \n 1.73205i\n \n 1.00000\n \n −\n \n 1.73205i\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n \\(158\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(159\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(160\\)\n \n −1.00000\n \n −\n \n 1.00000i\n \n −1.00000\n \n −\n \n 1.00000i\n
\n \\(161\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(162\\)\n \n\n \n\n \n 1.00000i\n \n\n \n\n \n 1.00000i\n
\n \\(163\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.258819\n \n −\n \n 0.965926i\n \n \\(-0.416667\\pi\\)\n
\n −0.258819\n \n +\n \n 0.965926i\n \n \\(0.583333\\pi\\)\n
\n \\(164\\)\n \n −1.36603\n \n +\n \n 0.366025i\n \n −1.36603\n \n +\n \n 0.366025i\n
\n \\(165\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(166\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(167\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.707107\n \n −\n \n 0.707107i\n \n \\(-0.250000\\pi\\)\n
\n −0.707107\n \n +\n \n 0.707107i\n \n \\(0.750000\\pi\\)\n
\n \\(168\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(169\\)\n \n −1.00000\n \n\n \n\n \n −1.00000\n \n\n \n\n
\n \\(170\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n
\n \\(171\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(172\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(173\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(174\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(175\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(176\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(177\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(178\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(179\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(180\\)\n \n 0.366025\n \n −\n \n 1.36603i\n \n 0.366025\n \n −\n \n 1.36603i\n
\n \\(181\\)\n \n 1.00000\n \n +\n \n 1.00000i\n \n 1.00000\n \n +\n \n 1.00000i\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(182\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(183\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(184\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(185\\)\n \n −1.73205\n \n −\n \n 1.00000i\n \n −1.73205\n \n −\n \n 1.00000i\n
\n \\(186\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(187\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(188\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(189\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(190\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(191\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(192\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(193\\)\n \n −1.36603\n \n +\n \n 0.366025i\n \n −1.36603\n \n +\n \n 0.366025i\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(194\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n
\n \\(195\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(196\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(197\\)\n \n 1.00000\n \n +\n \n 1.00000i\n \n 1.00000\n \n +\n \n 1.00000i\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(198\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(199\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.258819\n \n −\n \n 0.965926i\n \n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \n \\(0.416667\\pi\\)\n
\n \\(200\\)\n \n −0.500000\n \n +\n \n 0.866025i\n \n −0.500000\n \n +\n \n 0.866025i\n
\n \\(201\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(202\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(203\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(204\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(205\\)\n \n 1.00000\n \n +\n \n 1.73205i\n \n 1.00000\n \n +\n \n 1.73205i\n
\n \\(206\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(207\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(208\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(209\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(210\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(211\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.707107\n \n −\n \n 0.707107i\n \n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \n \\(0.250000\\pi\\)\n
\n \\(212\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(213\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(214\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(215\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(216\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(217\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(218\\)\n \n −1.00000\n \n +\n \n 1.00000i\n \n −1.00000\n \n +\n \n 1.00000i\n
\n \\(219\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(220\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(221\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(222\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(223\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(224\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(225\\)\n \n −1.00000\n \n\n \n\n \n −1.00000\n \n\n \n\n
\n \\(226\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n
\n \\(227\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.965926\n \n −\n \n 0.258819i\n \n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \n \\(0.916667\\pi\\)\n
\n \\(228\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(229\\)\n \n −1.73205\n \n +\n \n 1.00000i\n \n −1.73205\n \n +\n \n 1.00000i\n \n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(230\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(231\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(232\\)\n \n 1.00000\n \n +\n \n 1.00000i\n \n 1.00000\n \n +\n \n 1.00000i\n
\n \\(233\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(234\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(235\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(236\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(237\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(238\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(239\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(240\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(241\\)\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n \\(242\\)\n \n −0.500000\n \n +\n \n 0.866025i\n \n −0.500000\n \n +\n \n 0.866025i\n
\n \\(243\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(244\\)\n \n −1.00000\n \n −\n \n 1.00000i\n \n −1.00000\n \n −\n \n 1.00000i\n
\n \\(245\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(246\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(247\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(248\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(249\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(250\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(251\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(252\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(253\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(254\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(255\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(256\\)\n \n −0.500000\n \n +\n \n 0.866025i\n \n −0.500000\n \n +\n \n 0.866025i\n
\n \\(257\\)\n \n 1.73205\n \n −\n \n 1.00000i\n \n 1.73205\n \n −\n \n 1.00000i\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n \\(258\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(259\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(260\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(261\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n
\n \\(262\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(263\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(264\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(265\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(266\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(267\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(268\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(269\\)\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(270\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(271\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(272\\)\n \n 1.00000\n \n\n \n\n \n 1.00000\n \n\n \n\n
\n \\(273\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(274\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(275\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(276\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(277\\)\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(278\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(279\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(280\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(281\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(282\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(283\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.965926\n \n −\n \n 0.258819i\n \n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \n \\(0.916667\\pi\\)\n
\n \\(284\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(285\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(286\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(287\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(288\\)\n \n −1.00000\n \n\n \n\n \n −1.00000\n \n\n \n\n
\n \\(289\\)\n \n −0.500000\n \n −\n \n 0.866025i\n \n −0.500000\n \n −\n \n 0.866025i\n
\n \\(290\\)\n \n 1.00000\n \n −\n \n 1.73205i\n \n 1.00000\n \n −\n \n 1.73205i\n
\n \\(291\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(292\\)\n \n −1.36603\n \n −\n \n 0.366025i\n \n −1.36603\n \n −\n \n 0.366025i\n
\n \\(293\\)\n \n 2.00000\n \n\n \n\n \n 2.00000\n \n\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n \\(294\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(295\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(296\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n
\n \\(297\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(298\\)\n \n 1.73205\n \n +\n \n 1.00000i\n \n 1.73205\n \n +\n \n 1.00000i\n
\n \\(299\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(300\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(301\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(302\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(303\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(304\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(305\\)\n \n −1.00000\n \n +\n \n 1.73205i\n \n −1.00000\n \n +\n \n 1.73205i\n
\n \\(306\\)\n \n 0.500000\n \n +\n \n 0.866025i\n \n 0.500000\n \n +\n \n 0.866025i\n
\n \\(307\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(308\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(309\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(310\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(311\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.258819\n \n −\n \n 0.965926i\n \n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \n \\(0.416667\\pi\\)\n
\n \\(312\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(313\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n \n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(314\\)\n \n\n \n\n \n 2.00000i\n \n\n \n\n \n 2.00000i\n
\n \\(315\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(316\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(317\\)\n \n 0.366025\n \n −\n \n 1.36603i\n \n 0.366025\n \n −\n \n 1.36603i\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n \\(318\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(319\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(320\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n
\n \\(321\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(322\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(323\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(324\\)\n \n −0.500000\n \n −\n \n 0.866025i\n \n −0.500000\n \n −\n \n 0.866025i\n
\n \\(325\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(326\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(327\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(328\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n
\n \\(329\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(330\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(331\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(332\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(333\\)\n \n −1.36603\n \n +\n \n 0.366025i\n \n −1.36603\n \n +\n \n 0.366025i\n
\n \\(334\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(335\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(336\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(337\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n \\(338\\)\n \n 0.866025\n \n −\n \n 0.500000i\n \n 0.866025\n \n −\n \n 0.500000i\n
\n \\(339\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(340\\)\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.366025\n \n −\n \n 1.36603i\n
\n \\(341\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(342\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(343\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(344\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(345\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(346\\)\n \n −1.36603\n \n +\n \n 0.366025i\n \n −1.36603\n \n +\n \n 0.366025i\n
\n \\(347\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.965926\n \n −\n \n 0.258819i\n \n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \n \\(0.916667\\pi\\)\n
\n \\(348\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(349\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(350\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(351\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(352\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(353\\)\n \n −1.00000\n \n +\n \n 1.73205i\n \n −1.00000\n \n +\n \n 1.73205i\n \n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(354\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(355\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(356\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(357\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(358\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(359\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(360\\)\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.366025\n \n +\n \n 1.36603i\n
\n \\(361\\)\n \n 0.500000\n \n −\n \n 0.866025i\n \n 0.500000\n \n −\n \n 0.866025i\n
\n \\(362\\)\n \n −1.36603\n \n −\n \n 0.366025i\n \n −1.36603\n \n −\n \n 0.366025i\n
\n \\(363\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(364\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(365\\)\n \n\n \n\n \n 2.00000i\n \n\n \n\n \n 2.00000i\n
\n \\(366\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(367\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.965926\n \n −\n \n 0.258819i\n \n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \n \\(0.916667\\pi\\)\n
\n \\(368\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(369\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n
\n \\(370\\)\n \n 2.00000\n \n\n \n\n \n 2.00000\n \n\n \n\n
\n \\(371\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(372\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(373\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(374\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(375\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(376\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(377\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(378\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(379\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.707107\n \n −\n \n 0.707107i\n \n \\(-0.250000\\pi\\)\n
\n −0.707107\n \n +\n \n 0.707107i\n \n \\(0.750000\\pi\\)\n
\n \\(380\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(381\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(382\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(383\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(384\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(385\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(386\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n
\n \\(387\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(388\\)\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.366025\n \n −\n \n 1.36603i\n
\n \\(389\\)\n \n −1.73205\n \n −\n \n 1.00000i\n \n −1.73205\n \n −\n \n 1.00000i\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n \\(390\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(391\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(392\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(393\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(394\\)\n \n −1.36603\n \n −\n \n 0.366025i\n \n −1.36603\n \n −\n \n 0.366025i\n
\n \\(395\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(396\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(397\\)\n \n 0.366025\n \n −\n \n 1.36603i\n \n 0.366025\n \n −\n \n 1.36603i\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n \\(398\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(399\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(400\\)\n \n\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n
\n \\(401\\)\n \n 0.366025\n \n −\n \n 1.36603i\n \n 0.366025\n \n −\n \n 1.36603i\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n \\(402\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(403\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(404\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(405\\)\n \n −1.00000\n \n +\n \n 1.00000i\n \n −1.00000\n \n +\n \n 1.00000i\n
\n \\(406\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(407\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(408\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(409\\)\n \n −1.00000\n \n +\n \n 1.73205i\n \n −1.00000\n \n +\n \n 1.73205i\n \n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(410\\)\n \n −1.73205\n \n −\n \n 1.00000i\n \n −1.73205\n \n −\n \n 1.00000i\n
\n \\(411\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(412\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(413\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(414\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(415\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(416\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(417\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(418\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(419\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.707107\n \n −\n \n 0.707107i\n \n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \n \\(0.250000\\pi\\)\n
\n \\(420\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(421\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(422\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(423\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(424\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(425\\)\n \n −0.866025\n \n +\n \n 0.500000i\n \n −0.866025\n \n +\n \n 0.500000i\n
\n \\(426\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(427\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(428\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(429\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(430\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(431\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.965926\n \n −\n \n 0.258819i\n \n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \n \\(0.916667\\pi\\)\n
\n \\(432\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(433\\)\n \n\n \n\n \n 2.00000i\n \n\n \n\n \n 2.00000i\n \n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(434\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(435\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(436\\)\n \n 0.366025\n \n −\n \n 1.36603i\n \n 0.366025\n \n −\n \n 1.36603i\n
\n \\(437\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(438\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(439\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.965926\n \n −\n \n 0.258819i\n \n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \n \\(0.0833333\\pi\\)\n
\n \\(440\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(441\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(442\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(443\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(444\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(445\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(446\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(447\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(448\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(449\\)\n \n −1.00000\n \n −\n \n 1.00000i\n \n −1.00000\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(450\\)\n \n 0.866025\n \n −\n \n 0.500000i\n \n 0.866025\n \n −\n \n 0.500000i\n
\n \\(451\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(452\\)\n \n −1.36603\n \n +\n \n 0.366025i\n \n −1.36603\n \n +\n \n 0.366025i\n
\n \\(453\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(454\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(455\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(456\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(457\\)\n \n −1.73205\n \n +\n \n 1.00000i\n \n −1.73205\n \n +\n \n 1.00000i\n \n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(458\\)\n \n 1.00000\n \n −\n \n 1.73205i\n \n 1.00000\n \n −\n \n 1.73205i\n
\n \\(459\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(460\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(461\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(462\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(463\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(464\\)\n \n −1.36603\n \n −\n \n 0.366025i\n \n −1.36603\n \n −\n \n 0.366025i\n
\n \\(465\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(466\\)\n \n −1.36603\n \n +\n \n 0.366025i\n \n −1.36603\n \n +\n \n 0.366025i\n
\n \\(467\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(468\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(469\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(470\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(471\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(472\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(473\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(474\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(475\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(476\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(477\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(478\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(479\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.258819\n \n −\n \n 0.965926i\n \n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \n \\(0.416667\\pi\\)\n
\n \\(480\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(481\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(482\\)\n \n 1.00000\n \n +\n \n 1.00000i\n \n 1.00000\n \n +\n \n 1.00000i\n
\n \\(483\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(484\\)\n \n\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n
\n \\(485\\)\n \n −1.73205\n \n +\n \n 1.00000i\n \n −1.73205\n \n +\n \n 1.00000i\n
\n \\(486\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(487\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.965926\n \n −\n \n 0.258819i\n \n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \n \\(0.916667\\pi\\)\n
\n \\(488\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n
\n \\(489\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(490\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(491\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(492\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(493\\)\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.366025\n \n +\n \n 1.36603i\n
\n \\(494\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(495\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(496\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(497\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(498\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(499\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.258819\n \n −\n \n 0.965926i\n \n \\(-0.416667\\pi\\)\n
\n −0.258819\n \n +\n \n 0.965926i\n \n \\(0.583333\\pi\\)\n
\n \\(500\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(501\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(502\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(503\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.707107\n \n −\n \n 0.707107i\n \n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \n \\(0.250000\\pi\\)\n
\n \\(504\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(505\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(506\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(507\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(508\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(509\\)\n \n −1.00000\n \n −\n \n 1.73205i\n \n −1.00000\n \n −\n \n 1.73205i\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n \\(510\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(511\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(512\\)\n \n\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n
\n \\(513\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(514\\)\n \n −1.00000\n \n +\n \n 1.73205i\n \n −1.00000\n \n +\n \n 1.73205i\n
\n \\(515\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(516\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(517\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(518\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(519\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(520\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(521\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(522\\)\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.366025\n \n −\n \n 1.36603i\n
\n \\(523\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(524\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(525\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(526\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(527\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(528\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(529\\)\n \n −0.866025\n \n −\n \n 0.500000i\n \n −0.866025\n \n −\n \n 0.500000i\n
\n \\(530\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(531\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(532\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(533\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(534\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(535\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(536\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(537\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(538\\)\n \n −1.00000\n \n −\n \n 1.00000i\n \n −1.00000\n \n −\n \n 1.00000i\n
\n \\(539\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(540\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(541\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(542\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(543\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(544\\)\n \n −0.866025\n \n +\n \n 0.500000i\n \n −0.866025\n \n +\n \n 0.500000i\n
\n \\(545\\)\n \n −2.00000\n \n\n \n\n \n −2.00000\n \n\n \n\n
\n \\(546\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(547\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.707107\n \n −\n \n 0.707107i\n \n \\(-0.250000\\pi\\)\n
\n −0.707107\n \n +\n \n 0.707107i\n \n \\(0.750000\\pi\\)\n
\n \\(548\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(549\\)\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.366025\n \n +\n \n 1.36603i\n
\n \\(550\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(551\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(552\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(553\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(554\\)\n \n −1.00000\n \n −\n \n 1.00000i\n \n −1.00000\n \n −\n \n 1.00000i\n
\n \\(555\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(556\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(557\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(558\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(559\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(560\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(561\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(562\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(563\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(564\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(565\\)\n \n 1.00000\n \n +\n \n 1.73205i\n \n 1.00000\n \n +\n \n 1.73205i\n
\n \\(566\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(567\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(568\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(569\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(570\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(571\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.965926\n \n −\n \n 0.258819i\n \n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \n \\(0.916667\\pi\\)\n
\n \\(572\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(573\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(574\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(575\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(576\\)\n \n 0.866025\n \n −\n \n 0.500000i\n \n 0.866025\n \n −\n \n 0.500000i\n
\n \\(577\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(578\\)\n \n 0.866025\n \n +\n \n 0.500000i\n \n 0.866025\n \n +\n \n 0.500000i\n
\n \\(579\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(580\\)\n \n\n \n\n \n 2.00000i\n \n\n \n\n \n 2.00000i\n
\n \\(581\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(582\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(583\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(584\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n
\n \\(585\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(586\\)\n \n −1.73205\n \n +\n \n 1.00000i\n \n −1.73205\n \n +\n \n 1.00000i\n
\n \\(587\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(588\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(589\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(590\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(591\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(592\\)\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.366025\n \n −\n \n 1.36603i\n
\n \\(593\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(594\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(595\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(596\\)\n \n −2.00000\n \n\n \n\n \n −2.00000\n \n\n \n\n
\n \\(597\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(598\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(599\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(600\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(601\\)\n \n −1.00000\n \n −\n \n 1.00000i\n \n −1.00000\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(602\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(603\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(604\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(605\\)\n \n −1.36603\n \n +\n \n 0.366025i\n \n −1.36603\n \n +\n \n 0.366025i\n
\n \\(606\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(607\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.965926\n \n −\n \n 0.258819i\n \n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \n \\(0.0833333\\pi\\)\n
\n \\(608\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(609\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(610\\)\n \n\n \n −\n \n 2.00000i\n \n\n \n −\n \n 2.00000i\n
\n \\(611\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(612\\)\n \n −0.866025\n \n −\n \n 0.500000i\n \n −0.866025\n \n −\n \n 0.500000i\n
\n \\(613\\)\n \n −1.00000\n \n +\n \n 1.73205i\n \n −1.00000\n \n +\n \n 1.73205i\n \n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(614\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(615\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(616\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(617\\)\n \n −1.00000\n \n +\n \n 1.00000i\n \n −1.00000\n \n +\n \n 1.00000i\n \n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(618\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(619\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.965926\n \n −\n \n 0.258819i\n \n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \n \\(0.916667\\pi\\)\n
\n \\(620\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(621\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(622\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(623\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(624\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(625\\)\n \n −0.500000\n \n −\n \n 0.866025i\n \n −0.500000\n \n −\n \n 0.866025i\n
\n \\(626\\)\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.366025\n \n −\n \n 1.36603i\n
\n \\(627\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(628\\)\n \n −1.00000\n \n −\n \n 1.73205i\n \n −1.00000\n \n −\n \n 1.73205i\n
\n \\(629\\)\n \n −1.00000\n \n +\n \n 1.00000i\n \n −1.00000\n \n +\n \n 1.00000i\n
\n \\(630\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(631\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(632\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(633\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(634\\)\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.366025\n \n +\n \n 1.36603i\n
\n \\(635\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(636\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(637\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(638\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(639\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(640\\)\n \n −1.36603\n \n +\n \n 0.366025i\n \n −1.36603\n \n +\n \n 0.366025i\n
\n \\(641\\)\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.366025\n \n −\n \n 1.36603i\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n \\(642\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(643\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.707107\n \n −\n \n 0.707107i\n \n \\(-0.250000\\pi\\)\n
\n −0.707107\n \n +\n \n 0.707107i\n \n \\(0.750000\\pi\\)\n
\n \\(644\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(645\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(646\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(647\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(648\\)\n \n 0.866025\n \n +\n \n 0.500000i\n \n 0.866025\n \n +\n \n 0.500000i\n
\n \\(649\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(650\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(651\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(652\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(653\\)\n \n 0.366025\n \n −\n \n 1.36603i\n \n 0.366025\n \n −\n \n 1.36603i\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n \\(654\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(655\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(656\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n
\n \\(657\\)\n \n 1.00000\n \n +\n \n 1.00000i\n \n 1.00000\n \n +\n \n 1.00000i\n
\n \\(658\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(659\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(660\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(661\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(662\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(663\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(664\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(665\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(666\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n
\n \\(667\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(668\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(669\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(670\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(671\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(672\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(673\\)\n \n −1.00000\n \n −\n \n 1.00000i\n \n −1.00000\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(674\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n
\n \\(675\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(676\\)\n \n −0.500000\n \n +\n \n 0.866025i\n \n −0.500000\n \n +\n \n 0.866025i\n
\n \\(677\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(678\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(679\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(680\\)\n \n 1.00000\n \n +\n \n 1.00000i\n \n 1.00000\n \n +\n \n 1.00000i\n
\n \\(681\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(682\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(683\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.258819\n \n −\n \n 0.965926i\n \n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \n \\(0.416667\\pi\\)\n
\n \\(684\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(685\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(686\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(687\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(688\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(689\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(690\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(691\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.258819\n \n −\n \n 0.965926i\n \n \\(-0.416667\\pi\\)\n
\n −0.258819\n \n +\n \n 0.965926i\n \n \\(0.583333\\pi\\)\n
\n \\(692\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n
\n \\(693\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(694\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(695\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(696\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(697\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n
\n \\(698\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(699\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(700\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(701\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(702\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(703\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(704\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(705\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(706\\)\n \n\n \n −\n \n 2.00000i\n \n\n \n −\n \n 2.00000i\n
\n \\(707\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(708\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(709\\)\n \n −1.36603\n \n −\n \n 0.366025i\n \n −1.36603\n \n −\n \n 0.366025i\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(710\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(711\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(712\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(713\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(714\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(715\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(716\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(717\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(718\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(719\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.965926\n \n −\n \n 0.258819i\n \n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \n \\(0.0833333\\pi\\)\n
\n \\(720\\)\n \n −1.00000\n \n −\n \n 1.00000i\n \n −1.00000\n \n −\n \n 1.00000i\n
\n \\(721\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(722\\)\n \n\n \n\n \n 1.00000i\n \n\n \n\n \n 1.00000i\n
\n \\(723\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(724\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n
\n \\(725\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n
\n \\(726\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(727\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(728\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(729\\)\n \n\n \n\n \n 1.00000i\n \n\n \n\n \n 1.00000i\n
\n \\(730\\)\n \n −1.00000\n \n −\n \n 1.73205i\n \n −1.00000\n \n −\n \n 1.73205i\n
\n \\(731\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(732\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(733\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(734\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(735\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(736\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(737\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(738\\)\n \n −1.36603\n \n +\n \n 0.366025i\n \n −1.36603\n \n +\n \n 0.366025i\n
\n \\(739\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(740\\)\n \n −1.73205\n \n +\n \n 1.00000i\n \n −1.73205\n \n +\n \n 1.00000i\n
\n \\(741\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(742\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(743\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.707107\n \n −\n \n 0.707107i\n \n \\(-0.250000\\pi\\)\n
\n −0.707107\n \n +\n \n 0.707107i\n \n \\(0.750000\\pi\\)\n
\n \\(744\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(745\\)\n \n 0.732051\n \n +\n \n 2.73205i\n \n 0.732051\n \n +\n \n 2.73205i\n
\n \\(746\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(747\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(748\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(749\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(750\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(751\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.965926\n \n −\n \n 0.258819i\n \n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \n \\(0.0833333\\pi\\)\n
\n \\(752\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(753\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(754\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(755\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(756\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(757\\)\n \n\n \n\n \n 2.00000i\n \n\n \n\n \n 2.00000i\n \n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(758\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(759\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(760\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(761\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(762\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(763\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(764\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(765\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n
\n \\(766\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(767\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(768\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(769\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(770\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(771\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(772\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n
\n \\(773\\)\n \n −1.73205\n \n −\n \n 1.00000i\n \n −1.73205\n \n −\n \n 1.00000i\n \n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n −0.866025\n \n −\n \n 0.500000i\n \n \\(-0.833333\\pi\\)\n
\n \\(774\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(775\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(776\\)\n \n 1.00000\n \n +\n \n 1.00000i\n \n 1.00000\n \n +\n \n 1.00000i\n
\n \\(777\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(778\\)\n \n 2.00000\n \n\n \n\n \n 2.00000\n \n\n \n\n
\n \\(779\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(780\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(781\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(782\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(783\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(784\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(785\\)\n \n −2.00000\n \n +\n \n 2.00000i\n \n −2.00000\n \n +\n \n 2.00000i\n
\n \\(786\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(787\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.258819\n \n −\n \n 0.965926i\n \n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \n \\(0.416667\\pi\\)\n
\n \\(788\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n
\n \\(789\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(790\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(791\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(792\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(793\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(794\\)\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.366025\n \n +\n \n 1.36603i\n
\n \\(795\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(796\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(797\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(798\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(799\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(800\\)\n \n 0.500000\n \n +\n \n 0.866025i\n \n 0.500000\n \n +\n \n 0.866025i\n
\n \\(801\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(802\\)\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.366025\n \n +\n \n 1.36603i\n
\n \\(803\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(804\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(805\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(806\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(807\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(808\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(809\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(810\\)\n \n 0.366025\n \n −\n \n 1.36603i\n \n 0.366025\n \n −\n \n 1.36603i\n
\n \\(811\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.707107\n \n −\n \n 0.707107i\n \n \\(-0.250000\\pi\\)\n
\n −0.707107\n \n +\n \n 0.707107i\n \n \\(0.750000\\pi\\)\n
\n \\(812\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(813\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(814\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(815\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(816\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(817\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(818\\)\n \n\n \n −\n \n 2.00000i\n \n\n \n −\n \n 2.00000i\n
\n \\(819\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(820\\)\n \n 2.00000\n \n\n \n\n \n 2.00000\n \n\n \n\n
\n \\(821\\)\n \n −1.36603\n \n −\n \n 0.366025i\n \n −1.36603\n \n −\n \n 0.366025i\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(822\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(823\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.965926\n \n −\n \n 0.258819i\n \n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \n \\(0.916667\\pi\\)\n
\n \\(824\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(825\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(826\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(827\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.707107\n \n −\n \n 0.707107i\n \n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \n \\(0.250000\\pi\\)\n
\n \\(828\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(829\\)\n \n 1.00000\n \n −\n \n 1.73205i\n \n 1.00000\n \n −\n \n 1.73205i\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n \\(830\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(831\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(832\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(833\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(834\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(835\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(836\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(837\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(838\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(839\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.707107\n \n −\n \n 0.707107i\n \n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \n \\(0.250000\\pi\\)\n
\n \\(840\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(841\\)\n \n\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n
\n \\(842\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(843\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(844\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(845\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n
\n \\(846\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(847\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(848\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(849\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(850\\)\n \n 0.500000\n \n −\n \n 0.866025i\n \n 0.500000\n \n −\n \n 0.866025i\n
\n \\(851\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(852\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(853\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n \\(854\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(855\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(856\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(857\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(858\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(859\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(860\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(861\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(862\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(863\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(864\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(865\\)\n \n −1.73205\n \n −\n \n 1.00000i\n \n −1.73205\n \n −\n \n 1.00000i\n
\n \\(866\\)\n \n −1.00000\n \n −\n \n 1.73205i\n \n −1.00000\n \n −\n \n 1.73205i\n
\n \\(867\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(868\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(869\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(870\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(871\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(872\\)\n \n 0.366025\n \n +\n \n 1.36603i\n \n 0.366025\n \n +\n \n 1.36603i\n
\n \\(873\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n
\n \\(874\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(875\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(876\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(877\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n \n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(878\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(879\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(880\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(881\\)\n \n −1.00000\n \n +\n \n 1.00000i\n \n −1.00000\n \n +\n \n 1.00000i\n \n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(882\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(883\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(884\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(885\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(886\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(887\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.965926\n \n −\n \n 0.258819i\n \n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \n \\(0.0833333\\pi\\)\n
\n \\(888\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(889\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(890\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(891\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(892\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(893\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(894\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(895\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(896\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(897\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(898\\)\n \n 1.36603\n \n +\n \n 0.366025i\n \n 1.36603\n \n +\n \n 0.366025i\n
\n \\(899\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(900\\)\n \n −0.500000\n \n +\n \n 0.866025i\n \n −0.500000\n \n +\n \n 0.866025i\n
\n \\(901\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(902\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(903\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(904\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n
\n \\(905\\)\n \n −1.00000\n \n −\n \n 1.73205i\n \n −1.00000\n \n −\n \n 1.73205i\n
\n \\(906\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(907\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.965926\n \n −\n \n 0.258819i\n \n \\(-0.0833333\\pi\\)\n
\n −0.965926\n \n +\n \n 0.258819i\n \n \\(0.916667\\pi\\)\n
\n \\(908\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(909\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(910\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(911\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.707107\n \n −\n \n 0.707107i\n \n \\(-0.750000\\pi\\)\n
\n 0.707107\n \n +\n \n 0.707107i\n \n \\(0.250000\\pi\\)\n
\n \\(912\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(913\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(914\\)\n \n 1.00000\n \n −\n \n 1.73205i\n \n 1.00000\n \n −\n \n 1.73205i\n
\n \\(915\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(916\\)\n \n\n \n\n \n 2.00000i\n \n\n \n\n \n 2.00000i\n
\n \\(917\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(918\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(919\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.500000\n \n −\n \n 0.866025i\n \n \\(-0.666667\\pi\\)\n
\n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n \\(920\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(921\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(922\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(923\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(924\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(925\\)\n \n 1.00000\n \n +\n \n 1.00000i\n \n 1.00000\n \n +\n \n 1.00000i\n
\n \\(926\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(927\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(928\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n
\n \\(929\\)\n \n −0.366025\n \n +\n \n 1.36603i\n \n −0.366025\n \n +\n \n 1.36603i\n \n 0.500000\n \n +\n \n 0.866025i\n \n \\(0.333333\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(930\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(931\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(932\\)\n \n 1.00000\n \n −\n \n 1.00000i\n \n 1.00000\n \n −\n \n 1.00000i\n
\n \\(933\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(934\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(935\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(936\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(937\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 1.00000\n \n\n \n\n \n \\(0\\)\n
\n −1.00000\n \n\n \n\n \n \\(\\pi\\)\n
\n \\(938\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(939\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(940\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(941\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(942\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(943\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(944\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(945\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(946\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(947\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.965926\n \n −\n \n 0.258819i\n \n \\(-0.916667\\pi\\)\n
\n 0.965926\n \n +\n \n 0.258819i\n \n \\(0.0833333\\pi\\)\n
\n \\(948\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(949\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(950\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(951\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(952\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(953\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(954\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(955\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(956\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(957\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(958\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(959\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(960\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(961\\)\n \n −0.866025\n \n +\n \n 0.500000i\n \n −0.866025\n \n +\n \n 0.500000i\n
\n \\(962\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(963\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(964\\)\n \n −1.36603\n \n −\n \n 0.366025i\n \n −1.36603\n \n −\n \n 0.366025i\n
\n \\(965\\)\n \n 2.00000\n \n\n \n\n \n 2.00000\n \n\n \n\n
\n \\(966\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(967\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n\n \n −\n \n 1.00000i\n \n \\(-0.5\\pi\\)\n
\n\n \n\n \n 1.00000i\n \n \\(0.5\\pi\\)\n
\n \\(968\\)\n \n 0.500000\n \n +\n \n 0.866025i\n \n 0.500000\n \n +\n \n 0.866025i\n
\n \\(969\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(970\\)\n \n 1.00000\n \n −\n \n 1.73205i\n \n 1.00000\n \n −\n \n 1.73205i\n
\n \\(971\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.866025\n \n −\n \n 0.500000i\n \n \\(-0.166667\\pi\\)\n
\n −0.866025\n \n +\n \n 0.500000i\n \n \\(0.833333\\pi\\)\n
\n \\(972\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(973\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(974\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(975\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(976\\)\n \n −1.36603\n \n +\n \n 0.366025i\n \n −1.36603\n \n +\n \n 0.366025i\n
\n \\(977\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n −0.500000\n \n +\n \n 0.866025i\n \n \\(0.666667\\pi\\)\n
\n \\(978\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(979\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(980\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(981\\)\n \n −1.00000\n \n +\n \n 1.00000i\n \n −1.00000\n \n +\n \n 1.00000i\n
\n \\(982\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(983\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.258819\n \n −\n \n 0.965926i\n \n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \n \\(0.416667\\pi\\)\n
\n \\(984\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(985\\)\n \n −1.00000\n \n −\n \n 1.73205i\n \n −1.00000\n \n −\n \n 1.73205i\n
\n \\(986\\)\n \n −1.00000\n \n −\n \n 1.00000i\n \n −1.00000\n \n −\n \n 1.00000i\n
\n \\(987\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(988\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(989\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(990\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(991\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n \n −0.258819\n \n −\n \n 0.965926i\n \n \\(-0.583333\\pi\\)\n
\n 0.258819\n \n +\n \n 0.965926i\n \n \\(0.416667\\pi\\)\n
\n \\(992\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(993\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(994\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(995\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(996\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(997\\)\n \n 1.36603\n \n −\n \n 0.366025i\n \n 1.36603\n \n −\n \n 0.366025i\n \n 0.500000\n \n −\n \n 0.866025i\n \n \\(-0.333333\\pi\\)\n
\n 0.866025\n \n +\n \n 0.500000i\n \n \\(0.166667\\pi\\)\n
\n \\(998\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n \\(999\\)\n \n\n \n 0\n \n\n \n\n \n 0\n \n\n
\n
\n
\n \n Display \\(a_p\\) with \\(p\\) up to:\n 50\n 250\n 1000\n \n\n \n (See \\(a_n\\) instead)\n \n\n \n (See \\(a_n\\) instead)\n \n\n \n (See \\(a_n\\) instead)\n \n \n Display \\(a_n\\) with \\(n\\) up to:\n 50\n 250\n 1000\n \n\n \n (See only \\(a_p\\))\n \n\n \n (See only \\(a_p\\))\n \n\n \n (See only \\(a_p\\))\n \n
\n\n\n

Twists

\n\n\n\n\n \n \n \n \n \n \n \n\n\n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n
       By twisting character
CharParityOrdTypeTwistMinDim
1.1even1trivial3332.1.bc.b.2027.14
4.3odd2CM3332.1.bc.b.2027.14
7.2even3inner3332.1.bc.b.667.14
7.3odd668.1.f.a.55.1yes2
7.4even33332.1.m.b.2843.12
7.5odd63332.1.bc.c.667.14
7.6odd23332.1.bc.c.2027.14
17.13even4inner3332.1.bc.b.2223.14
21.17even6612.1.l.a.55.12
28.3even668.1.f.a.55.1yes2
28.11odd63332.1.m.b.2843.12
28.19even63332.1.bc.c.667.14
28.23odd6inner3332.1.bc.b.667.14
28.27even23332.1.bc.c.2027.14
35.3even121700.1.n.a.599.12
35.17even121700.1.n.b.599.12
35.24odd61700.1.p.a.1551.12
56.3even61088.1.p.a.191.12
56.45odd61088.1.p.a.191.12
68.47odd4inner3332.1.bc.b.2223.14
84.59odd6612.1.l.a.55.12
119.3even481156.1.g.b.155.18
119.10even481156.1.g.b.179.18
119.13odd43332.1.bc.c.2223.14
119.24even481156.1.g.b.179.28
119.30even12inner3332.1.bc.b.863.14
119.31even481156.1.g.b.155.28
119.38odd121156.1.f.b.251.12
119.45even481156.1.g.b.399.18
119.47odd123332.1.bc.c.863.14
119.59odd241156.1.c.b.579.12
119.66odd241156.1.d.a.1155.22
119.73even481156.1.g.b.423.28
119.80even481156.1.g.b.423.18
119.81even123332.1.m.b.3039.12
119.87odd241156.1.d.a.1155.12
119.94odd241156.1.c.b.579.22
119.101odd61156.1.f.b.327.12
119.108even481156.1.g.b.399.28
119.115odd1268.1.f.a.47.12
140.3odd121700.1.n.a.599.12
140.59even61700.1.p.a.1551.12
140.87odd121700.1.n.b.599.12
357.353even12612.1.l.a.523.12
476.3odd481156.1.g.b.155.18
476.31odd481156.1.g.b.155.28
476.47even123332.1.bc.c.863.14
476.59even241156.1.c.b.579.12
476.87even241156.1.d.a.1155.12
476.115even1268.1.f.a.47.12
476.143odd481156.1.g.b.179.28
476.199odd481156.1.g.b.423.18
476.227odd481156.1.g.b.399.28
476.251even43332.1.bc.c.2223.14
476.283odd481156.1.g.b.399.18
476.311odd481156.1.g.b.423.28
476.319odd123332.1.m.b.3039.12
476.339even61156.1.f.b.327.12
476.367odd481156.1.g.b.179.18
476.387odd12inner3332.1.bc.b.863.14
476.395even121156.1.f.b.251.12
476.423even241156.1.d.a.1155.22
476.451even241156.1.c.b.579.22
595.234odd121700.1.p.a.251.12
595.353even121700.1.n.b.999.12
595.472even121700.1.n.a.999.12
952.115even121088.1.p.a.319.12
952.829odd121088.1.p.a.319.12
1428.1067odd12612.1.l.a.523.12
2380.1067odd121700.1.n.a.999.12
2380.1543odd121700.1.n.b.999.12
2380.2019even121700.1.p.a.251.12
\n
    
\n\n\n\n\n \n \n \n \n \n \n \n\n\n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n \n \n \n \n \n \n \n\n\n
        By twisted newform
TwistMinDimCharParityOrdType
68.1.f.a.47.12119.115odd12
68.1.f.a.47.12476.115even12
68.1.f.a.55.1yes27.3odd6
68.1.f.a.55.1yes228.3even6
612.1.l.a.55.1221.17even6
612.1.l.a.55.1284.59odd6
612.1.l.a.523.12357.353even12
612.1.l.a.523.121428.1067odd12
1088.1.p.a.191.1256.3even6
1088.1.p.a.191.1256.45odd6
1088.1.p.a.319.12952.115even12
1088.1.p.a.319.12952.829odd12
1156.1.c.b.579.12119.59odd24
1156.1.c.b.579.12476.59even24
1156.1.c.b.579.22119.94odd24
1156.1.c.b.579.22476.451even24
1156.1.d.a.1155.12119.87odd24
1156.1.d.a.1155.12476.87even24
1156.1.d.a.1155.22119.66odd24
1156.1.d.a.1155.22476.423even24
1156.1.f.b.251.12119.38odd12
1156.1.f.b.251.12476.395even12
1156.1.f.b.327.12119.101odd6
1156.1.f.b.327.12476.339even6
1156.1.g.b.155.18119.3even48
1156.1.g.b.155.18476.3odd48
1156.1.g.b.155.28119.31even48
1156.1.g.b.155.28476.31odd48
1156.1.g.b.179.18119.10even48
1156.1.g.b.179.18476.367odd48
1156.1.g.b.179.28119.24even48
1156.1.g.b.179.28476.143odd48
1156.1.g.b.399.18119.45even48
1156.1.g.b.399.18476.283odd48
1156.1.g.b.399.28119.108even48
1156.1.g.b.399.28476.227odd48
1156.1.g.b.423.18119.80even48
1156.1.g.b.423.18476.199odd48
1156.1.g.b.423.28119.73even48
1156.1.g.b.423.28476.311odd48
1700.1.n.a.599.1235.3even12
1700.1.n.a.599.12140.3odd12
1700.1.n.a.999.12595.472even12
1700.1.n.a.999.122380.1067odd12
1700.1.n.b.599.1235.17even12
1700.1.n.b.599.12140.87odd12
1700.1.n.b.999.12595.353even12
1700.1.n.b.999.122380.1543odd12
1700.1.p.a.251.12595.234odd12
1700.1.p.a.251.122380.2019even12
1700.1.p.a.1551.1235.24odd6
1700.1.p.a.1551.12140.59even6
3332.1.m.b.2843.127.4even3
3332.1.m.b.2843.1228.11odd6
3332.1.m.b.3039.12119.81even12
3332.1.m.b.3039.12476.319odd12
3332.1.bc.b.667.147.2even3inner
3332.1.bc.b.667.1428.23odd6inner
3332.1.bc.b.863.14119.30even12inner
3332.1.bc.b.863.14476.387odd12inner
3332.1.bc.b.2027.141.1even1trivial
3332.1.bc.b.2027.144.3odd2CM
3332.1.bc.b.2223.1417.13even4inner
3332.1.bc.b.2223.1468.47odd4inner
3332.1.bc.c.667.147.5odd6
3332.1.bc.c.667.1428.19even6
3332.1.bc.c.863.14119.47odd12
3332.1.bc.c.863.14476.47even12
3332.1.bc.c.2027.147.6odd2
3332.1.bc.c.2027.1428.27even2
3332.1.bc.c.2223.14119.13odd4
3332.1.bc.c.2223.14476.251even4
\n
\n\n\n\n

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\n\n

This project is supported by grants from the US National Science Foundation, the UK Engineering and Physical Sciences Research Council, and the Simons Foundation.

\n
\n Contact\n ·\n Citation\n ·\n Acknowledgments\n ·\n Editorial Board\n ·\n Source\n ·\n SageMath version 10.1\n ·\n LMFDB Release 1.2.1\n
\n
\n\n", "statics": {"paragraph": 5, "paragraph.text": 24, "code": 8, "simple_table": 4, "title": 4, "complex_table": 5, "complex_table.complex": 5, "paragraph.equation-inline": 19}} diff --git a/docs/images/extract_method.png b/docs/images/extract_method.png new file mode 100644 index 00000000..7e9f24a4 Binary files /dev/null and b/docs/images/extract_method.png differ diff --git a/llm_web_kit/api/README.md b/llm_web_kit/api/README.md new file mode 100644 index 00000000..700e2de3 --- /dev/null +++ b/llm_web_kit/api/README.md @@ -0,0 +1,105 @@ +# LLM Web Kit API + +基于 FastAPI 的 LLM Web Kit API 服务,提供 HTML 解析功能。 + +## 功能特性 + +- 🚀 基于 FastAPI 的高性能 Web API +- 📄 HTML 内容解析与结构化输出 +- 🔗 支持 URL 和 HTML 字符串输入 +- 📁 支持 HTML 文件上传 +- 📚 自动生成的 API 文档 +- 🔧 可配置的解析选项 + +## 快速开始 + +配置环境变量 + +```bash +export MODEL_PATH="" +``` + +或者配置文件.llm-web-kit.jsonc添加“model_path” + +安装依赖 + +```bash +pip install -r requirements.txt +python llm_web_kit/api/run_server.py +``` + +- Swagger UI: http://127.0.0.1:8000/docs +- ReDoc: http://127.0.0.1:8000/redoc + +## API 端点 + +### HTML 解析 + +POST /api/v1/html/parse + +请求示例: + +```bash +curl -s -X POST "http://127.0.0.1:8000/api/v1/html/parse" \ + -H "Content-Type: application/json" \ + -d '{ + "html_content": "

Hello World

", + "url": "https://helloworld.com/hello", + "options": { + "clean_html": true + } + }' +``` + +或直接发送以下 JSON 作为请求体: + +```json +{ + "html_content": "

Hello World

", + "options": { + "clean_html": true + } +} +``` + +### 文件上传解析 + +POST /api/v1/html/upload + +```bash +curl -s -X POST "http://127.0.0.1:8000/api/v1/html/upload" \ + -F "file=@/path/to/file.html" +``` + +### 服务状态 + +GET /api/v1/html/status + +## 返回结构示例(/api/v1/html/parse 与 /api/v1/html/upload 成功返回) + +以下示例为 HTML 解析成功时的统一响应结构: + +```json +{ + "success": true, + "message": "HTML 解析成功", + "timestamp": "2025-08-26T16:45:43.140638", + "data": { + "layout_file_list": [], + "typical_raw_html": "

Hello World

", + "typical_raw_tag_html": "

Hello World

not main content

\n", + "llm_response": { + "item_id 1": 0, + "item_id 2": 1 + }, + "typical_main_html": "

Hello World

", + "html_target_list": ["Hello World"] + }, + "metadata": null +} +``` + +## 常见问题 + +- 422 错误:确认请求头 `Content-Type: application/json`,并确保请求体 JSON 合法。 +- 依赖缺失:`pip install -r llm_web_kit/api/requirements.txt`。 diff --git a/llm_web_kit/api/__init__.py b/llm_web_kit/api/__init__.py new file mode 100644 index 00000000..c2601bff --- /dev/null +++ b/llm_web_kit/api/__init__.py @@ -0,0 +1,7 @@ +"""LLM Web Kit API 模块. + +提供基于 FastAPI 的 Web API 接口,用于处理 HTML 解析和内容提取功能。 +""" + +__version__ = "1.0.0" +__author__ = "LLM Web Kit Team" diff --git a/llm_web_kit/api/dependencies.py b/llm_web_kit/api/dependencies.py new file mode 100644 index 00000000..32eadeb6 --- /dev/null +++ b/llm_web_kit/api/dependencies.py @@ -0,0 +1,78 @@ +"""API 依赖项管理. + +包含 FastAPI 应用的依赖项、配置管理和共享服务。 +""" + +import logging +from functools import lru_cache +from typing import Optional + +from pydantic_settings import BaseSettings, SettingsConfigDict + +logger = logging.getLogger(__name__) + + +class Settings(BaseSettings): + """应用配置设置.""" + + # API 配置 + api_title: str = "LLM Web Kit API" + api_version: str = "1.0.0" + api_description: str = "基于 LLM 的 Web 内容解析和提取 API 服务" + + # 服务器配置 + host: str = "0.0.0.0" + port: int = 8000 + debug: bool = False + + # 日志配置 + log_level: str = "INFO" + + # 模型配置 + model_path: Optional[str] = None + max_content_length: int = 10 * 1024 * 1024 # 10MB + + # 缓存配置 + cache_ttl: int = 3600 # 1小时 + + # pydantic v2 配置写法 + model_config = SettingsConfigDict( + env_file=".env", + case_sensitive=False + ) + + +@lru_cache() +def get_settings() -> Settings: + """获取应用配置单例.""" + return Settings() + + +def get_logger(name: str = __name__) -> logging.Logger: + """获取配置好的日志记录器.""" + logger = logging.getLogger(name) + if not logger.handlers: + handler = logging.StreamHandler() + formatter = logging.Formatter( + '%(asctime)s - %(name)s - %(levelname)s - %(message)s' + ) + handler.setFormatter(formatter) + logger.addHandler(handler) + logger.setLevel(get_settings().log_level) + return logger + + +# 全局依赖项 +settings = get_settings() + +# InferenceService 单例 +_inference_service_singleton = None + + +def get_inference_service(): + """获取 InferenceService 单例.""" + global _inference_service_singleton + if _inference_service_singleton is None: + from .services.inference_service import InferenceService + _inference_service_singleton = InferenceService() + return _inference_service_singleton diff --git a/llm_web_kit/api/main.py b/llm_web_kit/api/main.py new file mode 100644 index 00000000..18f71663 --- /dev/null +++ b/llm_web_kit/api/main.py @@ -0,0 +1,85 @@ +"""FastAPI 应用主入口. + +提供 LLM Web Kit 的 Web API 服务,包括 HTML 解析、内容提取等功能。 +""" + +import uvicorn +from fastapi import FastAPI +from fastapi.middleware.cors import CORSMiddleware +from fastapi.responses import JSONResponse + +from .dependencies import get_inference_service, get_logger, get_settings +from .routers import htmls + +settings = get_settings() +logger = get_logger(__name__) + + +# 创建 FastAPI 应用实例(元数据读取自 Settings) +app = FastAPI( + title=settings.api_title, + description=settings.api_description, + version=settings.api_version, + docs_url="/docs", + redoc_url="/redoc" +) + +# 添加 CORS 中间件 +app.add_middleware( + CORSMiddleware, + allow_origins=["*"], # 在生产环境中应该限制具体域名 + allow_credentials=True, + allow_methods=["*"], + allow_headers=["*"], +) + +# 注册路由 +app.include_router(htmls.router, prefix="/api/v1", tags=["HTML 处理"]) + + +@app.get("/") +async def root(): + """根路径,返回服务状态信息.""" + return { + "message": "LLM Web Kit API 服务运行中", + "version": settings.api_version, + "status": "healthy" + } + + +@app.get("/health") +async def health_check(): + """健康检查端点.""" + return {"status": "healthy", "service": "llm-web-kit-api"} + + +@app.on_event("startup") +async def app_startup(): + """应用启动时预热模型,避免首个请求冷启动延迟.""" + try: + service = get_inference_service() + await service.warmup() + logger.info("InferenceService 模型预热完成") + except Exception as e: + logger.warning(f"InferenceService 预热失败(服务仍可运行,将在首次请求时再初始化): {e}") + + +@app.exception_handler(Exception) +async def global_exception_handler(request, exc): + """全局异常处理器.""" + logger.error(f"未处理的异常: {exc}") + return JSONResponse( + status_code=500, + content={"detail": "服务器内部错误", "error": str(exc)} + ) + + +if __name__ == "__main__": + # 开发环境运行 + uvicorn.run( + "llm_web_kit.api.main:app", + host=settings.host, + port=settings.port, + reload=True, + log_level=(settings.log_level or "INFO").lower() + ) diff --git a/llm_web_kit/api/models/__init__.py b/llm_web_kit/api/models/__init__.py new file mode 100644 index 00000000..8f1a1ad6 --- /dev/null +++ b/llm_web_kit/api/models/__init__.py @@ -0,0 +1,13 @@ +"""Pydantic 模型模块. + +包含所有 API 请求和响应的数据模型定义。 +""" + +from .request import HTMLParseRequest +from .response import ErrorResponse, HTMLParseResponse + +__all__ = [ + "HTMLParseRequest", + "HTMLParseResponse", + "ErrorResponse" +] diff --git a/llm_web_kit/api/models/request.py b/llm_web_kit/api/models/request.py new file mode 100644 index 00000000..6fdb7269 --- /dev/null +++ b/llm_web_kit/api/models/request.py @@ -0,0 +1,41 @@ +"""请求数据模型. + +定义 API 请求的数据结构和验证规则。 +""" + +from typing import Any, Dict, Optional + +from pydantic import BaseModel, ConfigDict, Field + + +class HTMLParseRequest(BaseModel): + """HTML 解析请求模型.""" + + html_content: Optional[str] = Field( + None, + description="HTML 内容字符串", + max_length=10485760 # 10MB + ) + + url: Optional[str] = Field( + None, + description="url 地址", + max_length=10485760 # 10MB + ) + + options: Optional[Dict[str, Any]] = Field( + default_factory=dict, + description="解析选项配置" + ) + + model_config = ConfigDict( + json_schema_extra={ + "example": { + "html_content": "

Hello World

", + "url": "https://helloworld.com/hello", + "options": { + "clean_html": True + } + } + } + ) diff --git a/llm_web_kit/api/models/response.py b/llm_web_kit/api/models/response.py new file mode 100644 index 00000000..99fbf98f --- /dev/null +++ b/llm_web_kit/api/models/response.py @@ -0,0 +1,99 @@ +"""响应数据模型. + +定义 API 响应的数据结构和格式。 +""" + +from datetime import datetime +from typing import Any, Dict, List, Optional + +from pydantic import BaseModel, ConfigDict, Field + + +class ErrorResponse(BaseModel): + """错误响应模型.""" + + success: bool = Field(False, description="请求是否成功") + error: str = Field(..., description="错误信息") + detail: Optional[str] = Field(None, description="详细错误信息") + timestamp: datetime = Field(default_factory=datetime.now, description="错误发生时间") + + model_config = ConfigDict( + json_schema_extra={ + "example": { + "success": False, + "error": "HTML 解析失败", + "detail": "无效的 HTML 格式", + "timestamp": "2024-01-01T12:00:00" + } + } + ) + + +class BaseResponse(BaseModel): + """基础响应模型.""" + + success: bool = Field(..., description="请求是否成功") + message: str = Field(..., description="响应消息") + timestamp: datetime = Field(default_factory=datetime.now, description="响应时间") + + +class HTMLParseData(BaseModel): + """HTML 解析结果的结构化数据.""" + layout_file_list: List[str] = Field(default_factory=list, description="布局文件列表") + typical_raw_html: Optional[str] = Field(None, description="原始 HTML") + typical_raw_tag_html: Optional[str] = Field(None, description="带标签标注的原始 HTML") + llm_response: Dict[str, int] = Field(default_factory=dict, description="LLM 项目打标结果") + typical_main_html: Optional[str] = Field(None, description="解析得到的主体 HTML") + html_target_list: List[Any] = Field(default_factory=list, description="正文候选/目标列表") + + +class HTMLParseResponse(BaseResponse): + """HTML 解析响应模型.""" + + data: Optional[HTMLParseData] = Field(None, description="解析结果数据") + metadata: Optional[Dict[str, Any]] = Field(None, description="元数据信息") + + model_config = ConfigDict( + json_schema_extra={ + "example": { + "success": True, + "message": "HTML 解析成功", + "timestamp": "2025-08-26T16:45:43.140638", + "data": { + "layout_file_list": [], + "typical_raw_html": "

Hello World

", + "typical_raw_tag_html": "

Hello World

\n", + "llm_response": { + "item_id 1": 0, + "item_id 9": 1 + }, + "typical_main_html": "", + "html_target_list": [] + }, + "metadata": None + } + } + ) + + +class ServiceStatusResponse(BaseResponse): + """服务状态响应模型.""" + + service: str = Field(..., description="服务名称") + version: str = Field(..., description="服务版本") + status: str = Field(..., description="服务状态") + uptime: Optional[float] = Field(None, description="运行时间(秒)") + + model_config = ConfigDict( + json_schema_extra={ + "example": { + "success": True, + "message": "服务状态正常", + "timestamp": "2024-01-01T12:00:00", + "service": "HTML Processing Service", + "version": "1.0.0", + "status": "running", + "uptime": 3600.5 + } + } + ) diff --git a/llm_web_kit/api/requirements.txt b/llm_web_kit/api/requirements.txt new file mode 100644 index 00000000..c7cbd56f --- /dev/null +++ b/llm_web_kit/api/requirements.txt @@ -0,0 +1,21 @@ +# HTTP 客户端 +aiohttp>=3.9.0 + +# FastAPI 相关依赖 +fastapi>=0.104.0 +pydantic>=2.0.0 +pydantic-settings>=2.0.0 + +# 日志和配置 +python-dotenv>=1.0.0 + +# 数据处理 +python-multipart>=0.0.6 +torch==2.6.0 +transformers==4.52.4 + +# 类型提示支持 +uvicorn[standard]>=0.24.0 + +# 模型推理 +vllm==0.8.5.post1 diff --git a/llm_web_kit/api/routers/__init__.py b/llm_web_kit/api/routers/__init__.py new file mode 100644 index 00000000..4a3f1567 --- /dev/null +++ b/llm_web_kit/api/routers/__init__.py @@ -0,0 +1,8 @@ +"""路由模块. + +包含所有 API 路由定义,按功能模块组织。 +""" + +from . import htmls + +__all__ = ["htmls"] diff --git a/llm_web_kit/api/routers/htmls.py b/llm_web_kit/api/routers/htmls.py new file mode 100644 index 00000000..0f69074a --- /dev/null +++ b/llm_web_kit/api/routers/htmls.py @@ -0,0 +1,88 @@ +"""HTML 处理路由. + +提供 HTML 解析、内容提取等功能的 API 端点。 +""" + +from fastapi import APIRouter, Depends, File, HTTPException, UploadFile + +from ..dependencies import get_logger, get_settings +from ..models.request import HTMLParseRequest +from ..models.response import HTMLParseResponse +from ..services.html_service import HTMLService + +logger = get_logger(__name__) +settings = get_settings() + +router = APIRouter() + + +@router.post('/html/parse', response_model=HTMLParseResponse) +async def parse_html( + request: HTMLParseRequest, + html_service: HTMLService = Depends(HTMLService) +): + """解析 HTML 内容. + + 接收 HTML 字符串并返回解析后的结构化内容。 + """ + try: + logger.info(f'开始解析 HTML,内容长度: {len(request.html_content) if request.html_content else 0}') + + result = await html_service.parse_html( + html_content=request.html_content, + url=request.url, + options=request.options + ) + + return HTMLParseResponse( + success=True, + data=result, + message='HTML 解析成功' + ) + except Exception as e: + logger.error(f'HTML 解析失败: {str(e)}') + raise HTTPException(status_code=500, detail=f'HTML 解析失败: {str(e)}') + + +@router.post('/html/upload') +async def upload_html_file( + file: UploadFile = File(...), + html_service: HTMLService = Depends(HTMLService) +): + """上传 HTML 文件进行解析. + + 支持上传 HTML 文件,自动解析并返回结果。 + """ + try: + if not file.filename.endswith(('.html', '.htm')): + raise HTTPException(status_code=400, detail='只支持 HTML 文件') + + content = await file.read() + html_content = content.decode('utf-8') + + logger.info(f'上传 HTML 文件: {file.filename}, 大小: {len(content)} bytes') + + result = await html_service.parse_html(html_content=html_content) + + return HTMLParseResponse( + success=True, + data=result, + message='HTML 文件解析成功', + filename=file.filename + ) + except Exception as e: + logger.error(f'HTML 文件解析失败: {str(e)}') + raise HTTPException(status_code=500, detail=f'HTML 文件解析失败: {str(e)}') + + +@router.get('/html/status') +async def get_service_status(): + """获取服务状态. + + 返回 HTML 处理服务的当前状态信息。 + """ + return { + 'service': 'HTML Processing Service', + 'status': 'running', + 'version': '1.0.0' + } diff --git a/llm_web_kit/api/run_server.py b/llm_web_kit/api/run_server.py new file mode 100644 index 00000000..739b14fa --- /dev/null +++ b/llm_web_kit/api/run_server.py @@ -0,0 +1,29 @@ +#!/usr/bin/env python3 +"""API 服务器启动脚本. + +用于启动 LLM Web Kit API 服务。 +""" + +import os +import sys + +import uvicorn + +# 添加项目根目录到 Python 路径 +sys.path.insert(0, os.path.dirname(os.path.dirname(os.path.dirname(os.path.abspath(__file__))))) + +from llm_web_kit.api.dependencies import get_settings + +if __name__ == "__main__": + settings = get_settings() + print("启动 LLM Web Kit API 服务器...") + print(f"API 文档地址: http://{settings.host}:{settings.port}/docs") + print(f"ReDoc 文档地址: http://{settings.host}:{settings.port}/redoc") + + uvicorn.run( + "llm_web_kit.api.main:app", + host=settings.host, + port=settings.port, + reload=True, + log_level=(settings.log_level or "INFO").lower() + ) diff --git a/llm_web_kit/api/services/__init__.py b/llm_web_kit/api/services/__init__.py new file mode 100644 index 00000000..7e6717b1 --- /dev/null +++ b/llm_web_kit/api/services/__init__.py @@ -0,0 +1,8 @@ +"""服务层模块. + +包含业务逻辑服务,桥接原有项目功能。 +""" + +from .html_service import HTMLService + +__all__ = ["HTMLService"] diff --git a/llm_web_kit/api/services/html_service.py b/llm_web_kit/api/services/html_service.py new file mode 100644 index 00000000..46c6d4a3 --- /dev/null +++ b/llm_web_kit/api/services/html_service.py @@ -0,0 +1,81 @@ +"""HTML 处理服务. + +桥接原有项目的 HTML 解析和内容提取功能,提供统一的 API 接口。 +""" + +from typing import Any, Dict, Optional + +from ..dependencies import get_inference_service, get_logger, get_settings + +logger = get_logger(__name__) +settings = get_settings() + + +class HTMLService: + """HTML 处理服务类.""" + + def __init__(self): + """初始化 HTML 服务.""" + # 目前使用简化管线;使用全局单例的 InferenceService,避免重复初始化模型 + try: + self._inference_service = get_inference_service() + except Exception as e: + logger.warning(f'InferenceService 获取失败(将在首次调用时再尝试):{e}') + self._inference_service = None + + def _init_components(self): + """兼容保留(当前未使用)""" + return None + + async def parse_html( + self, + html_content: Optional[str] = None, + url: Optional[str] = None, + options: Optional[Dict[str, Any]] = None + ) -> Dict[str, Any]: + """解析 HTML 内容.""" + try: + if not html_content: + raise ValueError('必须提供 HTML 内容') + + # 延迟导入,避免模块导入期异常导致服务类不可用 + try: + from llm_web_kit.input.pre_data_json import (PreDataJson, + PreDataJsonKey) + from llm_web_kit.main_html_parser.parser.tag_mapping import \ + MapItemToHtmlTagsParser + from llm_web_kit.main_html_parser.simplify_html.simplify_html import \ + simplify_html + except Exception as import_err: + logger.error(f'依赖导入失败: {import_err}') + raise + + # 简化网页 + try: + simplified_html, typical_raw_tag_html = simplify_html(html_content) + except Exception as e: + logger.error(f'简化网页失败: {e}') + raise + + # 模型推理 + llm_response = await self._parse_with_model(simplified_html, options) + + # 结果映射 + pre_data = PreDataJson({}) + pre_data[PreDataJsonKey.TYPICAL_RAW_HTML] = html_content + pre_data[PreDataJsonKey.TYPICAL_RAW_TAG_HTML] = typical_raw_tag_html + pre_data[PreDataJsonKey.LLM_RESPONSE] = llm_response + parser = MapItemToHtmlTagsParser({}) + pre_data = parser.parse_single(pre_data) + + # 将 PreDataJson 转为标准 dict,避免响应模型校验错误 + return dict(pre_data.items()) + + except Exception as e: + logger.error(f'HTML解析失败: {e}') + raise + + async def _parse_with_model(self, html_content: str, options: Optional[Dict[str, Any]] = None) -> Dict[str, Any]: + if self._inference_service is None: + self._inference_service = get_inference_service() + return await self._inference_service.inference(html_content, options or {}) diff --git a/llm_web_kit/api/services/inference_service.py b/llm_web_kit/api/services/inference_service.py new file mode 100644 index 00000000..095404d9 --- /dev/null +++ b/llm_web_kit/api/services/inference_service.py @@ -0,0 +1,447 @@ +# vLLM 作为可选依赖:导入失败时保持模块可用,实际使用时再报错 +import json +import os +import re +import time +from dataclasses import dataclass +from enum import Enum +from typing import List + +import torch +from transformers import AutoTokenizer +from vllm import LLM, SamplingParams + +from llm_web_kit.config.cfg_reader import load_config + +from ..dependencies import get_logger + +logger = get_logger(__name__) + + +@dataclass +class InferenceConfig: + model_path: str = '' + data_path: str = '' + output_path: str = '' + use_logits_processor: bool = True + num_workers: int = 8 + max_tokens: int = 32768 + temperature: float = 0 + top_p: float = 0.95 + max_output_tokens: int = 8192 + tensor_parallel_size: int = 1 + # 正式环境修改为bfloat16 + dtype: str = 'float16' + template: bool = True + + +config = InferenceConfig( + model_path='', # checkpoint-3296路径 + output_path='', + use_logits_processor=True, # 启用逻辑处理器确保JSON格式输出 + num_workers=8, # 并行工作进程数 + max_tokens=26000, # 最大输入token数 + temperature=0, # 确定性输出 + top_p=0.95, + max_output_tokens=8192, # 最大输出token数 + tensor_parallel_size=1, # 张量并行大小 + template=True # 启用聊天模板 +) + +PROMPT = """As a front-end engineering expert in HTML, your task is to analyze the given HTML structure and accurately classify elements with the _item_id attribute as either "main" (primary content) or "other" (supplementary content). Your goal is to precisely extract the primary content of the page, ensuring that only the most relevant information is labeled as "main" while excluding navigation, metadata, and other non-essential elements. +Guidelines for Classification: +Primary Content ("main") +Elements that constitute the core content of the page should be classified as "main". These typically include: +✅ For Articles, News, and Blogs: +The main text body of the article, blog post, or news content. +Images embedded within the main content that contribute to the article. +✅ For Forums & Discussion Threads: +The original post in the thread. +Replies and discussions that are part of the main conversation. +✅ For Q&A Websites: +The question itself posted by a user. +Answers to the question and replies to answers that contribute to the discussion. +✅ For Other Content-Based Pages: +Any rich text, paragraphs, or media that serve as the primary focus of the page. +Supplementary Content ("other") +Elements that do not contribute to the primary content but serve as navigation, metadata, or supporting information should be classified as "other". These include: +❌ Navigation & UI Elements: +Menus, sidebars, footers, breadcrumbs, and pagination links. +"Skip to content" links and accessibility-related text. +❌ Metadata & User Information: +Article titles, author names, timestamps, and view counts. +Like counts, vote counts, and other engagement metrics. +❌ Advertisements & Promotional Content: +Any section labeled as "Advertisement" or "Sponsored". +Social media sharing buttons, follow prompts, and external links. +❌ Related & Suggested Content: +"Read More", "Next Article", "Trending Topics", and similar sections. +Lists of related articles, tags, and additional recommendations. +Task Instructions: +You will be provided with a simplified HTML structure containing elements with an _item_id attribute. Your job is to analyze each element's function and determine whether it should be classified as "main" or "other". +Response Format: +Return a JSON object where each key is the _item_id value, and the corresponding value is either "main" or "other", as in the following example: +{{"1": "other","2": "main","3": "other"}} +🚨 Important Notes: +Do not include any explanations in the output—only return the JSON. +Ensure high accuracy by carefully distinguishing between primary content and supplementary content. +Err on the side of caution—if an element seems uncertain, classify it as "other" unless it clearly belongs to the main content. + +Input HTML: +{alg_html} + +Output format should be a JSON-formatted string representing a dictionary where keys are item_id strings and values are either 'main' or 'other'. Make sure to include ALL item_ids from the input HTML. +""" + + +def create_prompt(alg_html: str) -> str: + return PROMPT.format(alg_html=alg_html) + + +def add_template(prompt: str, tokenizer: AutoTokenizer) -> str: + messages = [ + {'role': 'user', 'content': prompt} + ] + chat_prompt = tokenizer.apply_chat_template( + messages, + tokenize=False, + add_generation_prompt=True, + enable_thinking=True # Switches between thinking and non-thinking modes. Default is True. + ) + return chat_prompt + + +class State(Enum): + Left_bracket = 0 + Right_bracket = 1 + Space_quote = 2 + Quote_colon_quote = 3 + Quote_comma = 4 + Main_other = 5 + Number = 6 + + +class Token_state: + def __init__(self, model_path): + self.tokenizer = AutoTokenizer.from_pretrained(model_path, trust_remote_code=True) + token_id_map = { + State.Left_bracket: ['{'], + State.Right_bracket: ['}'], + State.Space_quote: [' "'], + State.Quote_colon_quote: ['":"'], + State.Quote_comma: ['",'], + State.Main_other: ['main', 'other'], + State.Number: ['0', '1', '2', '3', '4', '5', '6', '7', '8', '9'], + } + self.token_id_map = {k: [self.tokenizer.encode(v)[0] for v in token_id_map[k]] for k in token_id_map} + + def mask_other_logits(self, logits: torch.Tensor, remained_ids: List[int]): + remained_logits = {ids: logits[ids].item() for ids in remained_ids} + new_logits = torch.ones_like(logits) * -float('inf') + for id in remained_ids: + new_logits[id] = remained_logits[id] + return new_logits + + def calc_max_count(self, prompt_token_ids: List[int]): + pattern_list = [716, 1203, 842, 428] + for idx in range(len(prompt_token_ids) - len(pattern_list), -1, -1): + if all(prompt_token_ids[idx + i] == pattern_list[i] for i in range(len(pattern_list))): + num_idx = idx + len(pattern_list) + num_ids = [] + while num_idx < len(prompt_token_ids) and prompt_token_ids[num_idx] in self.token_id_map[State.Number]: + num_ids.append(prompt_token_ids[num_idx]) + num_idx += 1 + # return int(self.tokenizer.decode(num_ids)) + 1 + return int(self.tokenizer.decode(num_ids)) + return 1 + + def find_last_complete_number(self, input_ids: List[int]): + if not input_ids: + return -1, 'null', -1 + + tail_number_ids = [] + last_idx = len(input_ids) - 1 + while last_idx >= 0 and input_ids[last_idx] in self.token_id_map[State.Number]: + tail_number_ids.insert(0, input_ids[last_idx]) + last_idx -= 1 + + tail_number = int(self.tokenizer.decode(tail_number_ids)) if tail_number_ids else -1 + + while last_idx >= 0 and input_ids[last_idx] not in self.token_id_map[State.Number]: + last_idx -= 1 + + if last_idx < 0: + return tail_number, 'tail', tail_number + + last_number_ids = [] + while last_idx >= 0 and input_ids[last_idx] in self.token_id_map[State.Number]: + last_number_ids.insert(0, input_ids[last_idx]) + last_idx -= 1 + + last_number = int(self.tokenizer.decode(last_number_ids)) + + if tail_number == last_number + 1: + return tail_number, 'tail', tail_number + return last_number, 'non_tail', tail_number + + def process_logit(self, prompt_token_ids: List[int], input_ids: List[int], logits: torch.Tensor): + if not input_ids: + return self.mask_other_logits(logits, self.token_id_map[State.Left_bracket]) + + last_token = input_ids[-1] + + if last_token == self.token_id_map[State.Right_bracket][0]: + return self.mask_other_logits(logits, [151645]) + elif last_token == self.token_id_map[State.Left_bracket][0]: + return self.mask_other_logits(logits, self.token_id_map[State.Space_quote]) + elif last_token == self.token_id_map[State.Space_quote][0]: + last_number, _, _ = self.find_last_complete_number(input_ids) + # next_char = str(last_number + 1)[0] + if last_number == -1: + next_char = '1' + else: + next_char = str(last_number + 1)[0] + + return self.mask_other_logits(logits, self.tokenizer.encode(next_char)) + elif last_token in self.token_id_map[State.Number]: + last_number, state, tail_number = self.find_last_complete_number(input_ids) + if state == 'tail': + return self.mask_other_logits(logits, self.token_id_map[State.Quote_colon_quote]) + else: + next_str = str(last_number + 1) + next_char = next_str[len(str(tail_number))] + return self.mask_other_logits(logits, self.tokenizer.encode(next_char)) + elif last_token == self.token_id_map[State.Quote_colon_quote][0]: + return self.mask_other_logits(logits, self.token_id_map[State.Main_other]) + elif last_token in self.token_id_map[State.Main_other]: + return self.mask_other_logits(logits, self.token_id_map[State.Quote_comma]) + elif last_token == self.token_id_map[State.Quote_comma][0]: + last_number, _, _ = self.find_last_complete_number(input_ids) + max_count = self.calc_max_count(prompt_token_ids) + if last_number >= max_count: + return self.mask_other_logits(logits, self.token_id_map[State.Right_bracket]) + else: + return self.mask_other_logits(logits, self.token_id_map[State.Space_quote]) + + return logits + + +def reformat_map(text): + try: + data = json.loads(text) + return {'item_id ' + k: 1 if v == 'main' else 0 for k, v in data.items()} + except json.JSONDecodeError: + return {} + + +def main(simplified_html: str, model: object, tokenizer: object, model_path: str): + # tokenizer = AutoTokenizer.from_pretrained("/share/liukaiwen/models/qwen3-0.6b/checkpoint-3296", trust_remote_code=True) + # simplified_html = simplify_html(ori_html) + # print("sim_html length", len(simplified_html)) + if SamplingParams is None: + raise RuntimeError( + '当前环境未安装 vLLM 或安装失败,无法执行模型推理。建议在 Linux+NVIDIA GPU 环境安装 vLLM,' + + '或在 API 中使用占位/替代推理实现。原始导入错误: {}'.format('_VLLM_IMPORT_ERROR') + ) + prompt = create_prompt(simplified_html) + chat_prompt = add_template(prompt, tokenizer) + + if config.use_logits_processor: + token_state = Token_state(model_path) + sampling_params = SamplingParams( + temperature=config.temperature, + top_p=config.top_p, + max_tokens=config.max_output_tokens, + logits_processors=[token_state.process_logit] + ) + else: + sampling_params = SamplingParams( + temperature=config.temperature, + top_p=config.top_p, + max_tokens=config.max_output_tokens + ) + + output = model.generate(chat_prompt, sampling_params) + output_json = clean_output(output) + return output_json + + +def clean_output(output): + prediction = output[0].outputs[0].text + + # Extract JSON from prediction + start_idx = prediction.rfind('{') + end_idx = prediction.rfind('}') + 1 + + if start_idx != -1 and end_idx != -1: + json_str = prediction[start_idx:end_idx] + json_str = re.sub(r',\s*}', '}', json_str) # Clean JSON + try: + json.loads(json_str) # Validate + except Exception: + json_str = '{}' + else: + json_str = '{}' + + return json_str + + +class InferenceService: + """对外暴露的推理服务封装,供 HTMLService 调用。""" + + def __init__(self): + """初始化推理服务,延迟加载模型.""" + self._llm = None + self._tokenizer = None + self._initialized = False + self._init_lock = None # 用于异步初始化锁 + self._model_path = None + + async def warmup(self): + """在服务启动阶段主动预热模型(异步初始化)。""" + await self._ensure_initialized() + + async def _ensure_initialized(self): + """确保模型已初始化(异步安全)""" + if not self._initialized: + if self._init_lock is None: + import asyncio + self._init_lock = asyncio.Lock() + + async with self._init_lock: + if not self._initialized: # 双重检查 + await self._init_model() + self._initialized = True + + async def _init_model(self): + """初始化模型和tokenizer.""" + try: + llm_config = load_config(suppress_error=True) + self.model_path = os.environ['MODEL_PATH'] if 'MODEL_PATH' in os.environ else llm_config.get('model_path', + None) + if self.model_path is None: + raise RuntimeError('model_path为空,未配置模型路径') + if SamplingParams is None: + raise RuntimeError( + '当前环境未安装 vLLM 或安装失败,无法执行模型推理。建议在 Linux+NVIDIA GPU 环境安装 vLLM,' + + '或在 API 中使用占位/替代推理实现。原始导入错误: {}'.format('_VLLM_IMPORT_ERROR') + ) + + # 初始化 tokenizer + self._tokenizer = AutoTokenizer.from_pretrained( + self.model_path, + trust_remote_code=True + ) + + # 初始化 LLM 模型 + self._llm = LLM( + model=self.model_path, + trust_remote_code=True, + dtype=config.dtype, + tensor_parallel_size=config.tensor_parallel_size, + # 正式环境删掉 + max_model_len=config.max_tokens, # 减少序列长度避免内存不足 + ) + + logger.info(f'模型初始化成功: {self.model_path}') + + except Exception as e: + logger.error(f'模型初始化失败: {e}') + # 如果模型初始化失败,保持为 None,后续调用会返回占位结果 + self._llm = None + self._tokenizer = None + + async def inference(self, simplified_html: str, options: dict | None = None) -> dict: + """执行推理,如果模型未初始化则返回占位结果.""" + try: + await self._ensure_initialized() + + if self._llm is None or self._tokenizer is None: + logger.error('模型未初始化,返回占位结果') + return self._get_placeholder_result() + + # 执行真实推理 + return await self._run_real_inference(simplified_html, options) + + except Exception as e: + logger.error(f'推理过程出错: {e}') + return self._get_placeholder_result() + + async def _run_real_inference(self, simplified_html: str, options: dict | None = None) -> dict: + """执行真实的模型推理.""" + try: + # 创建 prompt + prompt = create_prompt(simplified_html) + chat_prompt = add_template(prompt, self._tokenizer) + + # 设置采样参数 + if config.use_logits_processor: + token_state = Token_state(self.model_path) + sampling_params = SamplingParams( + temperature=config.temperature, + top_p=config.top_p, + max_tokens=config.max_output_tokens, + logits_processors=[token_state.process_logit] + ) + else: + sampling_params = SamplingParams( + temperature=config.temperature, + top_p=config.top_p, + max_tokens=config.max_output_tokens + ) + + # 执行推理 + start_time = time.time() + output = self._llm.generate(chat_prompt, sampling_params) + end_time = time.time() + output_json = clean_output(output) + + # 格式化结果 + result = reformat_map(output_json) + logger.info(f'推理完成,结果: {result}, 耗时: {end_time - start_time}秒') + return result + + except Exception as e: + logger.error(f'真实推理失败: {e}') + return self._get_placeholder_result() + + def _get_placeholder_result(self) -> dict: + """返回占位结果.""" + return {} + + +if __name__ == '__main__': + config = InferenceConfig( + model_path='', + output_path='', + use_logits_processor=True, + num_workers=8, + max_tokens=26000, + temperature=0, + top_p=0.95, + max_output_tokens=8192, + tensor_parallel_size=1, + template=True, + ) + try: + llm_config = load_config(suppress_error=True) + model_path = llm_config.get('model_path', None) + tokenizer = AutoTokenizer.from_pretrained(model_path, trust_remote_code=True) + model = LLM(model=model_path, + trust_remote_code=True, + dtype=config.dtype, + # 设置最大模型长度 + max_model_len=config.max_tokens, + tensor_parallel_size=config.tensor_parallel_size) + + simplified_html = '

Hello World

' + response_json = main(simplified_html, model, tokenizer) + llm_response_dict = reformat_map(response_json) + except Exception: + raise + finally: + import torch.distributed as dist + + # 在程序结束前添加 + if dist.is_initialized(): + dist.destroy_process_group() diff --git a/llm_web_kit/config/pipe_tpl/model.jsonc b/llm_web_kit/config/pipe_tpl/model.jsonc new file mode 100644 index 00000000..ff77efe5 Binary files /dev/null and b/llm_web_kit/config/pipe_tpl/model.jsonc differ diff --git a/llm_web_kit/extractor/html/post_main_html_processer/README.md b/llm_web_kit/extractor/html/post_main_html_processer/README.md index b6141c4e..ceb5a1c8 100644 --- a/llm_web_kit/extractor/html/post_main_html_processer/README.md +++ b/llm_web_kit/extractor/html/post_main_html_processer/README.md @@ -2,14 +2,94 @@ ## 流程方案 -![img.png](asserts/img.png) +![img.png](assets/img.png) ## 执行步骤 -| filename | function | input & input_type | output_type | 实现功能 | -| :--------------- | :-------------------------- | :-------------------------------------------------------- | :------------------ | :------------- | -| choose_html.py | select_typical_html | html_strs: html迭代器 | str | 选出代表html | -| add_tags.py | process_html | input_html: str | str | 添加itemid | -| post_llm.py | get_llm_response | api_key: str, url: str, html_id_str: str, model_name: str | str | 模型打标 | -| generate_rule.py | restore_html_trim_ends_only | processed_html: str, llm_response: Dict\[str, int\] | Dict\[str, object\] | 生成删除规则 | -| post_mapping.py | mapping_html_by_rules | html_str: str, post_delete_node: List\[object\] | str | 推广到所有数据 | +### choose_html.py 选出代表html + +``` +func: select_typical_htmls + +输入参数: + html_strings: List[dict] + [ + {"html": "html字符串","filename": "数据来源路径"} + ] + select_n: int (选出代表html的数量,default: 3) + +输出参数: + List[dict] + [ + {"html": "html字符串","filename": "数据来源路径"} + ] +``` + +### post_llm.py 模型识别生成规则 + +``` +func: get_llm_response + +输入参数: + html_strings: List[dict] + ["html0", "html1", "html2"] + api_key: str (openai api key) + url: str (openai api url) + model_name: str (openai model name) + +输出参数: + str + [ + { + "xpath": "//div[@class='et_pb_social_media_follow']", + "parent_tag": "div", + "parent_attributes": { + "class": "et_pb_column et_pb_column_2_3 et_pb_column_6 et_pb_css_mix_blend_mode_passthrough et-last-child" + }, + "reson": "Social media follow links are non-core content, typically used for sharing and external linking." + }, + { + "xpath": "//form[@class='et_pb_contact_form clearfix']", + "parent_tag": "div", + "parent_attributes": { + "class": "et_pb_column et_pb_column_2_3 et_pb_column_6 et_pb_css_mix_blend_mode_passthrough et-last-child" + }, + "reson": "Contact form is a footer widget, often considered as part of the contact section rather than main content." + } + ] +``` + +### post_mapping.py 推广到所有数据 + +``` +func: mapping_html_by_rules + +输入参数: + html_content: str + xpaths_to_remove: List[dict] + [ + { + "xpath": "//div[@class='et_pb_social_media_follow']", + "parent_tag": "div", + "parent_attributes": { + "class": "et_pb_column et_pb_column_2_3 et_pb_column_6 et_pb_css_mix_blend_mode_passthrough et-last-child" + }, + "reson": "Social media follow links are non-core content, typically used for sharing and external linking." + }, + { + "xpath": "//form[@class='et_pb_contact_form clearfix']", + "parent_tag": "div", + "parent_attributes": { + "class": "et_pb_column et_pb_column_2_3 et_pb_column_6 et_pb_css_mix_blend_mode_passthrough et-last-child" + }, + "reson": "Contact form is a footer widget, often considered as part of the contact section rather than main content." + } + ] + +输出参数: + tuple[str, bool] + ( + html_content, # html字符串 + is_success # 推广是否成功 + ) +``` diff --git a/llm_web_kit/extractor/html/post_main_html_processer/add_tags.py b/llm_web_kit/extractor/html/post_main_html_processer/add_tags.py deleted file mode 100644 index 63066cf8..00000000 --- a/llm_web_kit/extractor/html/post_main_html_processer/add_tags.py +++ /dev/null @@ -1,136 +0,0 @@ -from typing import Generator - -from lxml import etree - -from llm_web_kit.libs.html_utils import element_to_html, html_to_element - - -def process_html(input_html: str) -> str: - """处理HTML,为元素添加连续的_item_id属性. - - Args: - input_html: 输入的HTML字符串 - - Returns: - 处理后的HTML字符串,其中每个文本节点都有唯一的_item_id - """ - if not input_html: - return '' - - try: - tree = html_to_element(input_html) - root = tree.xpath('//body')[0] if tree.xpath('//body') else tree - except Exception as e: - raise ValueError(f'Invalid HTML input: {e}') - - # 使用ID生成器确保ID连续 - id_generator = __item_id_generator() - - # 遍历所有元素并处理 - __process_elements(root, id_generator) - - return element_to_html(root) - - -def __item_id_generator() -> Generator[int, None, None]: - """生成连续的ID序列. - - Yields: - 连续递增的整数ID - """ - counter = 1 - while True: - yield counter - counter += 1 - - -def __process_elements(tree: etree.Element, id_generator: Generator[int, None, None]) -> None: - """处理DOM树中的所有元素,为文本节点添加_item_id. - - Args: - tree: HTML DOM树根节点 - id_generator: ID生成器 - """ - # 创建静态列表避免在迭代时修改DOM结构 - elements_to_process = list(tree.iter()) - - for element in elements_to_process: - # 处理叶子节点(无子元素) - if len(element) == 0: - __process_leaf_element(element, id_generator) - else: - # 处理非叶子节点 - __process_non_leaf_element(element, id_generator) - - -def __process_leaf_element(element: etree.Element, - id_generator: Generator[int, None, None]) -> None: - """处理叶子节点元素. - - Args: - element: 叶子节点元素 - id_generator: ID生成器 - """ - # 为叶子节点分配_item_id - element.set('_item_id', str(next(id_generator))) - - # 处理tail文本 - if element.tail and element.tail.strip(): - parent = element.getparent() - if parent is not None: - # 创建custom_tail元素并插入到当前元素之后 - custom_tail = __create_custom_element( - 'custom_tail', element.tail, id_generator - ) - element.tail = None - - # 插入到正确位置 - parent_index = parent.index(element) - parent.insert(parent_index + 1, custom_tail) - - -def __process_non_leaf_element(element: etree.Element, - id_generator: Generator[int, None, None]) -> None: - """处理非叶子节点元素. - - Args: - element: 非叶子节点元素 - id_generator: ID生成器 - """ - parent = element.getparent() - parent_index = parent.index(element) if parent is not None else -1 - - # 处理元素的text内容 - if element.text and element.text.strip(): - custom_text = __create_custom_element( - 'custom_text', element.text, id_generator - ) - element.text = None - element.insert(0, custom_text) - - # 处理元素的tail内容 - if element.tail and element.tail.strip(): - if parent is not None: - custom_tail = __create_custom_element( - 'custom_tail', element.tail, id_generator - ) - element.tail = None - parent.insert(parent_index + 1, custom_tail) - - -def __create_custom_element(tag: str, text_content: str, - id_generator: Generator[int, None, None]) -> etree.Element: - """创建带_item_id的自定义元素. - - Args: - tag: 元素标签名 - text_content: 元素文本内容 - id_generator: ID生成器 - - Returns: - 带_item_id属性的自定义元素 - """ - custom_elem = etree.Element(tag) - custom_elem.text = text_content - custom_elem.set('_item_id', str(next(id_generator))) - return custom_elem diff --git a/llm_web_kit/extractor/html/post_main_html_processer/asserts/img.png b/llm_web_kit/extractor/html/post_main_html_processer/asserts/img.png deleted file mode 100644 index d516393f..00000000 Binary files a/llm_web_kit/extractor/html/post_main_html_processer/asserts/img.png and /dev/null differ diff --git a/llm_web_kit/extractor/html/post_main_html_processer/assets/html0.html b/llm_web_kit/extractor/html/post_main_html_processer/assets/html0.html new file mode 100644 index 00000000..5d353acb --- /dev/null +++ b/llm_web_kit/extractor/html/post_main_html_processer/assets/html0.html @@ -0,0 +1,1377 @@ + + + + +
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+ + + + + diff --git a/llm_web_kit/extractor/html/post_main_html_processer/assets/img.png b/llm_web_kit/extractor/html/post_main_html_processer/assets/img.png new file mode 100644 index 00000000..9293b16f Binary files /dev/null and b/llm_web_kit/extractor/html/post_main_html_processer/assets/img.png differ diff --git a/llm_web_kit/extractor/html/post_main_html_processer/assets/llm_res.json b/llm_web_kit/extractor/html/post_main_html_processer/assets/llm_res.json new file mode 100644 index 00000000..a4b6afac --- /dev/null +++ b/llm_web_kit/extractor/html/post_main_html_processer/assets/llm_res.json @@ -0,0 +1,26 @@ +[ + { + "xpath": "//div[@class='et_pb_section_1 et_pb_with_background et_section_regular']", + "parent_tag": "div", + "parent_attributes": { + "id": "main-content" + }, + "reson": "This section contains contact information and social media links, which are typically non-core content placed at the bottom of a webpage." + }, + { + "xpath": "//ul[@class='et_pb_module et_pb_social_media_follow et_pb_social_media_follow_0 clearfix et_pb_text_align_center et_pb_bg_layout_light']", + "parent_tag": "div", + "parent_attributes": { + "class": "et_pb_section_1 et_pb_with_background et_section_regular" + }, + "reson": "This is a social media follow block, commonly considered non-core content and usually found at the bottom of pages." + }, + { + "xpath": "//form[@class='et_pb_contact_form clearfix']", + "parent_tag": "div", + "parent_attributes": { + "class": "et_pb_section_1 et_pb_with_background et_section_regular" + }, + "reson": "This is a contact form, often used for user interaction but not central to the main page content." + } +] diff --git a/llm_web_kit/extractor/html/post_main_html_processer/assets/rule.json b/llm_web_kit/extractor/html/post_main_html_processer/assets/rule.json new file mode 100644 index 00000000..14f98c55 --- /dev/null +++ b/llm_web_kit/extractor/html/post_main_html_processer/assets/rule.json @@ -0,0 +1,23 @@ +[ + { + "xpath": "//div[@class='breadcrumb']", + "parent_tag": "div", + "parent_attributes": { + "class": "master-wrapper-content" + } + }, + { + "xpath": "//div[@class='product-selectors']", + "parent_tag": "div", + "parent_attributes": { + "class": "page-body" + } + }, + { + "xpath": "//div[@class='pager']", + "parent_tag": "div", + "parent_attributes": { + "class": "page-body" + } + } +] diff --git a/llm_web_kit/extractor/html/post_main_html_processer/choose_html.py b/llm_web_kit/extractor/html/post_main_html_processer/choose_html.py index 7e59d356..83beb5dd 100644 --- a/llm_web_kit/extractor/html/post_main_html_processer/choose_html.py +++ b/llm_web_kit/extractor/html/post_main_html_processer/choose_html.py @@ -1,6 +1,228 @@ -from typing import Generator +from collections import Counter +from typing import List +from lxml import etree -def select_typical_html(html_strs: Generator[str]) -> str: - """从多个HTML中选出头部和尾部最复杂的html.""" - pass +from llm_web_kit.libs.html_utils import html_to_element + +IGNORE_TAGS = {'script', 'style', 'meta', 'link', 'br', 'noscript'} +# 语义化标签 +SEMANTIC_TAGS = { + 'header', 'nav', 'main', 'article', 'section', 'aside', + 'footer', 'figure', 'figcaption', 'time', 'mark', 'summary', + 'details', 'h1', 'h2', 'h3', 'h4', 'h5', 'h6' +} +# 交互标签 +INTERACTIVE_TAGS = {'a', 'button', 'input', 'select', 'textarea', 'img', 'audio', 'video'} +# 各项指标的权重 +WEIGHTS = { + 'tag_diversity': 0.25, # 标签多样性权重 + 'total_elements': 0.2, # 元素总数权重 + 'max_depth': 0.15, # 嵌套深度权重 + 'semantic_tags': 0.25, # 语义标签权重 + 'styled_elements': 0.1, # 样式元素权重 + 'interactive_elements': 0.05 # 交互元素权重 +} + + +def select_typical_htmls(html_strings: List[dict], select_n: int = 3) -> List[dict]: + """从多个HTML中选择最具代表性的select_n个HTML. + + Args: + html_strings: + { + "html": "html字符串", + "filename": "html路径" + } + select_n: 需要选择的HTML数量,默认为3 + + Returns: + 选中的HTML字符串列表 + """ + if not html_strings: + return [] + + # 分析每个HTML + html_analysis = [] + for htmlstr_file in html_strings: + try: + analysis = __analyze_html_structure(htmlstr_file['html']) + if analysis: + analysis['html'] = htmlstr_file['html'] + analysis['filename'] = htmlstr_file['filename'] + html_analysis.append(analysis) + except Exception: + continue + + # 根据多个维度评分并排序 + scored_htmls = [] + for analysis in html_analysis: + score = __calculate_representativeness_score(analysis) + scored_htmls.append({ + 'html': analysis['html'], + 'filename': analysis['filename'], + 'score': score, + 'analysis': analysis + }) + + # 按分数排序并选择前select_n个 + scored_htmls.sort(key=lambda x: x['score'], reverse=True) + return scored_htmls[:select_n] if scored_htmls else [] + + +def __analyze_html_structure(html_str: str) -> dict: + """分析HTML结构特征. + + Args: + html_str: HTML字符串 + + Returns: + 包含分析结果的字典 + """ + try: + tree = html_to_element(html_str) + except Exception: + return None + + # 获取所有元素 + all_elements = list(tree.iter()) + + # 过滤有效标签 + valid_elements = [elem for elem in all_elements if __is_valid_tag(elem.tag)] + + if not valid_elements: + return None + + # 统计标签类型 + tag_counter = Counter(elem.tag for elem in valid_elements) + + # 计算结构复杂度指标 + metrics = { + # 标签多样性 + 'tag_diversity': len(tag_counter), + + # 总元素数 + 'total_elements': len(valid_elements), + + # 嵌套深度 + 'max_depth': __calculate_max_depth(tree), + + # 结构化语义标签使用情况 + 'semantic_tags': __count_semantic_tags(valid_elements), + + # CSS类和ID的使用 + 'styled_elements': __count_styled_elements(valid_elements), + + # 链接和媒体元素 + 'interactive_elements': __count_interactive_elements(valid_elements), + } + + return metrics + + +def __is_valid_tag(tag: str) -> bool: + """检查是否为有效的HTML标签.""" + return (tag and isinstance(tag, str) and + tag not in IGNORE_TAGS and + not tag.startswith(' int: + """计算DOM树的最大深度. + + Args: + element: 根元素 + + Returns: + 最大深度 + """ + if not element.getchildren(): + return 1 + + max_child_depth = 0 + for child in element.getchildren(): + if __is_valid_tag(child.tag): + child_depth = __calculate_max_depth(child) + max_child_depth = max(max_child_depth, child_depth) + + return max_child_depth + 1 + + +def __count_semantic_tags(elements: List[etree.Element]) -> int: + """计算语义化标签的数量. + + Args: + elements: 元素列表 + + Returns: + 语义化标签数量 + """ + return len([elem for elem in elements if elem.tag in SEMANTIC_TAGS]) + + +def __count_styled_elements(elements: List[etree.Element]) -> int: + """计算有样式属性的元素数量. + + Args: + elements: 元素列表 + + Returns: + 有样式属性的元素数量 + """ + count = 0 + for elem in elements: + if 'class' in elem.attrib or 'id' in elem.attrib: + count += 1 + return count + + +def __count_interactive_elements(elements: List[etree.Element]) -> int: + """计算交互元素数量. + + Args: + elements: 元素列表 + + Returns: + 交互元素数量 + """ + + return len([elem for elem in elements if elem.tag in INTERACTIVE_TAGS]) + + +def __calculate_representativeness_score(analysis: dict) -> float: + """计算HTML的代表性分数. + + Args: + analysis: HTML分析结果 + + Returns: + 代表性分数 + """ + if not analysis: + return 0.0 + + # 归一化各项指标(避免某些指标过大影响结果) + normalized_scores = {} + + # 标签多样性得分 (通常10-30种标签) + normalized_scores['tag_diversity'] = min(analysis.get('tag_diversity', 0) / 20.0, 1.0) + + # 元素总数得分 (通常几十到几百个元素) + normalized_scores['total_elements'] = min(analysis.get('total_elements', 0) / 100.0, 1.0) + + # 嵌套深度得分 (通常2-10层) + normalized_scores['max_depth'] = min(analysis.get('max_depth', 0) / 8.0, 1.0) + + # 语义标签得分 + normalized_scores['semantic_tags'] = min(analysis.get('semantic_tags', 0) / 10.0, 1.0) + + # 样式元素得分 + normalized_scores['styled_elements'] = min(analysis.get('styled_elements', 0) / 20.0, 1.0) + + # 交互元素得分 + normalized_scores['interactive_elements'] = min(analysis.get('interactive_elements', 0) / 10.0, 1.0) + + # 计算加权总分 + total_score = sum(normalized_scores[key] * WEIGHTS[key] for key in WEIGHTS) + + return total_score diff --git a/llm_web_kit/extractor/html/post_main_html_processer/generate_rule.py b/llm_web_kit/extractor/html/post_main_html_processer/generate_rule.py deleted file mode 100644 index 74d743a7..00000000 --- a/llm_web_kit/extractor/html/post_main_html_processer/generate_rule.py +++ /dev/null @@ -1,340 +0,0 @@ -import re -from typing import Dict, List, Optional - -from lxml import etree - -from llm_web_kit.html_layout.html_layout_cosin import (RE_MD5, RE_NUM, RE_SHA1, - RE_TIMESTAMP, RE_UUID) -from llm_web_kit.libs.html_utils import element_to_html, html_to_element - - -def restore_html_trim_ends_only(processed_html: str, llm_response: Dict[str, int]) -> Dict[str, object]: - """只删除HTML开头和结尾连续状态为0的元素,保留其他所有元素, 并删除所有的_item_id属性。同时将删除的节点信息记录在 - post_delete_node 字段中,删除规则。 - - Args: - processed_html: 带有_item_id属性的HTML字符串 - llm_response: LLM的响应,格式为 {'item_id 1': 0, 'item_id 2': 1, ...} - 0表示删除,1表示保留 - - Returns: - { 'html': 处理后的HTML字符串, 'post_delete_node': List[dict] } - """ - if not processed_html: - return {'html': '', 'post_delete_node': []} - if not llm_response: - # 如果没有LLM响应,则返回原始HTML - return {'html': processed_html, 'post_delete_node': []} - - try: - tree = html_to_element(processed_html) - except Exception as e: - raise ValueError(f'Invalid HTML input: {e}') - - # 预处理LLM响应:转换为{item_id: 状态}的字典 - item_status = {} - for key, status in llm_response.items(): - # 提取'item_id X'中的数字X作为item_id - item_id = int(key.split()[1]) - item_status[item_id] = status - - # 只处理开头和结尾的删除元素,并记录删除信息 - deletion_logger = _DeletionLogger() - __trim_ends_only(tree, item_status, deletion_logger) - - # 移除所有_item_id属性 - __remove_all_item_id_attributes(tree) - - return {'html': element_to_html(tree), 'post_delete_node': deletion_logger.records} - - -def __trim_ends_only( - tree: etree.Element, - item_status: Dict[int, int], - deletion_logger: '_DeletionLogger', -) -> None: - """只删除开头和结尾连续状态为0的元素. - - Args: - tree: HTML DOM树根节点 - item_status: 元素状态字典 - """ - # 获取所有带_item_id的元素 - elements = tree.xpath('//*[@_item_id]') - if not elements: - return - - # 从开头删除连续状态为0的元素 - start_index = 0 - while start_index < len(elements): - element = elements[start_index] - try: - item_id = int(element.get('_item_id', '')) - except ValueError: - start_index += 1 - continue - - status = item_status.get(item_id, 1) - if status == 0: - # 记录并删除元素及内容,并检查父节点是否需要删除 - __remove_element_and_check_parent( - root=tree, - element=element, - del_location='start', - deletion_logger=deletion_logger - ) - start_index += 1 - else: - break # 遇到保留状态的元素,停止删除 - - # 重新获取元素列表(因为可能有变化) - elements = tree.xpath('//*[@_item_id]') - if not elements: - return - - # 从结尾删除连续状态为0的元素 - end_index = len(elements) - 1 - while end_index >= 0: - element = elements[end_index] - try: - item_id = int(element.get('_item_id', '')) - except ValueError: - end_index -= 1 - continue - - status = item_status.get(item_id, 1) - if status == 0: - # 记录并删除元素及内容,并检查父节点是否需要删除 - __remove_element_and_check_parent( - root=tree, - element=element, - del_location='end', - deletion_logger=deletion_logger - ) - end_index -= 1 - else: - break # 遇到保留状态的元素,停止删除 - - -def __remove_element_and_check_parent( - *, - root: etree.Element, - element: etree.Element, - del_location: str, - deletion_logger: '_DeletionLogger', -) -> None: - """删除元素并检查其父节点是否需要删除. - - Args: - element: 要删除的元素 - """ - # 在移除前记录要删除的元素 - deletion_logger.record_element(root, element, del_location) - - parent = element.getparent() - if parent is None: - return - - # 记录父节点原始状态 - parent_has_item_id = '_item_id' in parent.attrib - - # 直接从父节点中移除元素 - parent.remove(element) - - # 如果父节点有_item_id,不需要进一步处理 - if parent_has_item_id: - return - - # 检查父节点是否还有子元素或者文本内容 - __check_and_remove_empty_parent(root, parent, del_location, deletion_logger) - - -def __check_and_remove_empty_parent( - root: etree.Element, parent: etree.Element, del_location: str, deletion_logger: '_DeletionLogger' -) -> None: - """检查父节点是否为空,如果为空则删除它(递归检查) - - Args: - parent: 要检查的父节点 - """ - # 检查父节点是否为空(没有子元素且没有文本内容) - last_snapshot: Optional[dict] = None - while parent is not None and __is_element_empty(parent): - grandparent = parent.getparent() - - # 如果父节点有_item_id,停止递归 - if '_item_id' in parent.attrib: - break - - # 如果没有父节点(已经是根节点),停止递归 - if grandparent is None: - break - - # 在移除前拍摄快照,用于最终仅记录最顶层被级联删除的父节点 - last_snapshot = deletion_logger.snapshot_element(root, parent, del_location) - # 移除空的父节点 - grandparent.remove(parent) - parent = grandparent - - # 仅在存在级联删除时,记录一次父节点删除,并清理其所有子节点的记录 - if last_snapshot is not None: - deletion_logger.prune_descendants_and_record_parent(last_snapshot) - - -class _DeletionLogger: - """记录被删除节点的信息,并在父节点被级联删除时,仅保留父节点记录。 - - 记录字段示例: - { - 'xpath': '/html/body/div[1]/p[2]', - 'tag': 'p', - 'attributes': {'class': 'note', 'id': 'note'}, - 'index_in_parent': 1, - 'parent_xpath': '/html/body/div[1]', - 'parent_tag': 'div', - 'parent_attributes': {'class': 'container', 'id': 'container'} - } - """ - - def __init__(self) -> None: - self.records: List[dict] = [] - self._xpaths: set[str] = set() - - def _compute_xpath(self, root: etree.Element, element: etree.Element) -> str: - # 使用 root 构建 ElementTree,并计算 element 的 XPath - try: - return etree.ElementTree(root).getpath(element) - except Exception: - # 尝试使用 element 自己的 roottree - try: - return element.getroottree().getpath(element) - except Exception: - return '' - - def snapshot_element(self, root: etree.Element, element: etree.Element, del_location: str) -> dict: - xpath = self._compute_xpath(root, element) - parent = element.getparent() - parent_xpath = self._compute_xpath(root, parent) if parent is not None else '' - parent_tag = parent.tag if parent is not None else '' - parent_attributes = self.parse_attrs(parent) if parent is not None else {} - - index_in_parent = -1 - if parent is not None: - try: - index_in_parent = list(parent).index(element) - except ValueError: - index_in_parent = -1 - - attrs = self.parse_attrs(element) - - snapshot = { - 'del_location': del_location, - 'xpath': xpath, - 'tag': element.tag, - 'attributes': attrs, - 'index_in_parent': index_in_parent, - 'parent_xpath': parent_xpath, - 'parent_tag': parent_tag, - 'parent_attributes': parent_attributes, - } - return snapshot - - def parse_attrs(self, element: etree.Element) -> Dict: - attrs = {k: self.dynamic_attributes_preprocess(v) for k, v in element.attrib.items() if - k in ['class', 'id']} if element.attrib else {} - return attrs - - def dynamic_attributes_preprocess(self, attr_str: str) -> str: - """动态属性值标准化处理.""" - res_attr_str = '' - if attr_str: - attr_lst = attr_str.split() - if len(attr_lst) > 1: - res_attr_str = ' '.join([i for i in attr_lst if not RE_NUM.search(i)]) - elif len(attr_lst) == 1: - res_attr_str = self.standardizing_dynamic_attributes(attr_lst[0]) - return res_attr_str - - def standardizing_dynamic_attributes(self, attr_value: str) -> str: - """将动态属性值标准化为统一表示.""" - if RE_MD5.fullmatch(attr_value): - return '[MD5]' - if RE_SHA1.fullmatch(attr_value): - return '[SHA1]' - if RE_UUID.fullmatch(attr_value): - return '[UUID]' - if RE_TIMESTAMP.fullmatch(attr_value): - return '[TIMESTAMP]' - if RE_NUM.search(attr_value): - return re.sub(r'\d+', '', attr_value) - - return attr_value - - def record_element(self, root: etree.Element, element: etree.Element, del_location: str) -> None: - snap = self.snapshot_element(root, element, del_location) - # 去重:相同 xpath 的记录只保留一次(优先保留先记录的) - if snap['xpath'] and snap['xpath'] not in self._xpaths: - self.records.append(snap) - self._xpaths.add(snap['xpath']) - - def prune_descendants_and_record_parent(self, parent_snapshot: dict) -> None: - """删除所有位于 parent_snapshot['xpath'] 之下的子节点记录,仅保留父节点记录。""" - parent_xpath = parent_snapshot.get('xpath', '') - if not parent_xpath: - return - - # 过滤掉所有子孙节点记录 - kept: List[dict] = [] - new_xpaths: set[str] = set() - prefix = parent_xpath + '/' - for rec in self.records: - xp = rec.get('xpath', '') - if xp == parent_xpath or xp.startswith(prefix): - # 丢弃,稍后添加父节点快照 - continue - kept.append(rec) - if xp: - new_xpaths.add(xp) - - # 添加父节点快照(若未存在) - if parent_xpath not in new_xpaths: - kept.append(parent_snapshot) - new_xpaths.add(parent_xpath) - - self.records = kept - self._xpaths = new_xpaths - - -def __is_element_empty(element: etree.Element) -> bool: - """检查元素是否为空(没有子元素且没有有意义的文本内容) - - Args: - element: 要检查的元素 - - Returns: - 如果元素为空返回True,否则返回False - """ - # 检查是否有子元素 - if len(element) > 0: - return False - - # 检查是否有文本内容 - if element.text and element.text.strip(): - return False - - # 检查是否有tail内容 - if element.tail and element.tail.strip(): - return False - - return True - - -def __remove_all_item_id_attributes(tree: etree.Element) -> None: - """移除DOM树中所有元素的_item_id属性. - - Args: - tree: HTML DOM树根节点 - """ - for element in tree.iter(): - if '_item_id' in element.attrib: - del element.attrib['_item_id'] diff --git a/llm_web_kit/extractor/html/post_main_html_processer/post_llm.py b/llm_web_kit/extractor/html/post_main_html_processer/post_llm.py index 579ce1cf..d30120cf 100644 --- a/llm_web_kit/extractor/html/post_main_html_processer/post_llm.py +++ b/llm_web_kit/extractor/html/post_main_html_processer/post_llm.py @@ -1,99 +1,100 @@ -from loguru import logger -from openai import BadRequestError, OpenAI +import re +from pathlib import Path +from typing import List from llm_web_kit.libs.standard_utils import json_loads -html_str = """ - -
-
-
-
-
-
-
-
-
-

All right... We have returned from Romania again! It was a pleasure - to slash you - with quality metal once again. Thanks to Manu, the - beginning of the - performance at TATTOO & MUSIC FEST II in Iasi could be - seen below... -
- Thanks to all, who managed to attend the events, meet us and help us on the way! - You know who you are!
- Stay tuned! News coming soon...

- -

-
- - -
-
-
-
-
-
-
-
- -""" - -promtp = f"""你是文本识别专家,输入一个html字符串,且每个标签都有一个属性值不同的属性_item_id,你通过识别html能够解析出每个_item_id对应的内容是否是主体内容,主要在于去除以下两部分的内容: -1.去除头部导航栏、时间、作者、广告、推荐等非正文主体内容; -2.去除尾部链接、分享、翻页、广告、推荐等非正文主体内容。 -注意,主体内容链接保留 -识别出主体内容之后根据_item_id生成字典作为返回结果,无需解释生成依据,其中0代表非主体内容需要去除,1代表是主体内容要保留。示例如下: -输入: {html_str} -返回结果: {{'item_id 1': 1, 'item_id 2': 1, 'item_id 3': 1, 'item_id 4': 1, 'item_id 5': 1, 'item_id 6': 1, 'item_id 7': 1, 'item_id 8': 1, 'item_id 9': 1, 'item_id 10': 1, 'item_id 11': 1, 'item_id 12': 1, 'item_id 13': 1, 'item_id 14': 1, 'item_id 15': 1, 'item_id 16': 1, 'item_id 17': 1, 'item_id 18': 1, 'item_id 19': 0, 'item_id 20': 0, 'item_id 21': 0, 'item_id 22': 0, 'item_id 23': 0, 'item_id 24': 0, 'item_id 25': 0, 'item_id 26': 0, 'item_id 27': 0}} -""" - - -def get_llm_response(api_key: str, url: str, html_id_str: str, model_name: str) -> dict: - # Set OpenAI's API key and API base to use vLLM's API server. +base_dir = Path(__file__).parent + + +def __get_eg_data(): + eg_input_lst = [] + for i in range(3): + eg_input_lst.append(base_dir.joinpath(f'assets/html{i}.html').read_text(encoding='utf-8')) + + eg_output = json_loads(base_dir.joinpath('assets/rule.json').read_text(encoding='utf-8')) + return eg_input_lst, eg_output + + +output_format = '''[ + { + "xpath": "XPath of the node of the non-core content body", + "parent_tag": "The label name of the parent node of the node that is not the core content body", + "parent_attributes": "The class and id attributes of the parent node of the node that is not the core content body", + "reson": "Reasons for determining it as non-core content" + } +]''' + + +def clean_json_data(md_text: str) -> dict: + cleaned = re.sub(r'^```json|\```', '', md_text, flags=re.MULTILINE) + try: + json_data = json_loads(cleaned) + except Exception: + return None + return json_data + + +def get_llm_response(input_lst: List, api_key: str, url: str, model_name: str, is_llm: bool = True, + max_retry: int = 3) -> dict: + if not is_llm: + post_llm_response = base_dir.joinpath('assets/llm_res.json').read_text(encoding='utf-8') + return json_loads(post_llm_response) + + from openai import BadRequestError, OpenAI + client = OpenAI( # 若没有配置环境变量,请用百炼API Key将下行替换为:api_key='sk-xxx', api_key=api_key, base_url=url, ) - content = f"""{promtp}以下是需要判断的html代码: - ``` - {html_id_str} - ``` - 返回结果: - """ + html_count = len(input_lst) + eg_input_lst, eg_output = __get_eg_data() + + prompt = f""" +You are an expert in HTML semantics and will be assigned the following task: +Accept input:{input_lst}containing{html_count}HTML pages. +The input has the following characteristics: +1. These{html_count}HTML pages are from the same website. +2. These{html_count}pages use the same template, differing only in their main content. +################ +The tasks you need to complete are: +Deeply understand the{html_count}HTML input and find the node information and node paths for the non-core content at the page header (top section) and page footer (bottom section) of the {html_count} HTML. +################ +You need to follow the following rules when completing the task: +1. Identify and extract non-core content modules located in the page header (top section) and page footer (bottom section) of the HTML body. Do not identify the main title as non-core content. Non-core content includes breadcrumb navigation, related article links, advertisements, page turning, sharing, recommended content, etc. +2. If non-core content appears in the middle of the HTML, such as the time and author in a forum reply, it can be ignored. +3. If a node contains non-core content main nodes and core content main nodes, its internal elements need to be further analyzed; if a node is a wrapper for the entire page content or a container node containing multiple child elements, its internal elements need to be further analyzed. +4. Tables have semantic ambiguity. When analyzing table nodes, we need to consider the following: if they present structured data (such as product tables or data reports), they are classified as core content. If they are used for layout or display of simple lists (such as navigation menus or link lists), there are two cases: if it is a complete table structure, mark the entire table as non-core content. If it is an incomplete table structure or complex nesting, further analysis of its internal elements is required. +5. Non-core content should be carefully analyzed to prevent misjudgment. Uncertain elements should be excluded from non-core content. +6. It is necessary to consider the location of the HTML node of the non-core content body and the commonality of semantics in the web page. +7. When considering node paths, semantics should be prioritized. Avoid using indexes in node paths. Attribute values should be correct, especially those composed of multiple values. All attributes should be correctly matched. +8. Use '//' and '/' correctly when considering node paths. '//' is used for recursive searches, while '/' is used to locate direct children. +9. When considering node paths, always use the element's original tag name in the HTML source code. +10. Each node of the final non-core content body must have only one type of content, and the content of this node must be determined to be all non-core content bodies, without inclusion relationships or uncertain factors. +################ +The return data needs to follow the following rules: +1. Both node attributes and parent node attributes only consider the id attribute and class attribute. If both the id attribute and the class attribute are empty, they are ignored. +2. The returned node path must be unique and no duplicates are allowed. +3. The result is returned in JSON array format, requiring all strings to be enclosed in double quotes and not containing any additional information. The output format is as follows: +{output_format} +################ +Here are some examples for your reference: + +input:{eg_input_lst} +return:{eg_output} + +################ +Now return your result:""" try: completion = client.chat.completions.create( model=model_name, + # 此处以qwen-plus为例,可按需更换模型名称。模型列表:https://help.aliyun.com/zh/model-studio/getting-started/models extra_body={'enable_thinking': False}, messages=[ - {'role': 'system', 'content': 'You are a text recognition expert.'}, - {'role': 'user', 'content': content} + {'role': 'system', 'content': 'You are a HTML semantics expert.'}, + {'role': 'user', 'content': prompt} ], ) @@ -101,10 +102,11 @@ def get_llm_response(api_key: str, url: str, html_id_str: str, model_name: str) rtn = completion.model_dump_json() rtn_detail = json_loads(rtn) post_llm_response = rtn_detail.get('choices', [])[0].get('message', {}).get('content', '') - if '}' not in post_llm_response: - logger.exception(f'post_llm_response more than token limit, post_llm_response: {post_llm_response}') - return None - return post_llm_response - except BadRequestError as e: - logger.exception(e) + return clean_json_data(post_llm_response) + except BadRequestError: return None + except Exception: + if max_retry > 0: + return get_llm_response(input_lst, api_key, url, model_name, is_llm, max_retry - 1) + else: + return None diff --git a/llm_web_kit/extractor/html/post_main_html_processer/post_mapping.py b/llm_web_kit/extractor/html/post_main_html_processer/post_mapping.py index ba396d89..27dc876b 100644 --- a/llm_web_kit/extractor/html/post_main_html_processer/post_mapping.py +++ b/llm_web_kit/extractor/html/post_main_html_processer/post_mapping.py @@ -1,13 +1,98 @@ from typing import List +from lxml import html -def mapping_html_by_rules(html_str: str, post_delete_node: List[object]) -> str: +from llm_web_kit.libs.html_utils import element_to_html, html_to_element + + +def mapping_html_by_rules(html_content: str, xpaths_to_remove: List[dict]) -> tuple[str, bool]: + """从HTML中删除指定XPath匹配的所有节点. + + 参数: + html_content (str): 原始HTML内容 + xpaths_to_remove (list): 需要删除的元素列表 + + 返回: + str: 处理后的HTML + bool: 推广是否成功 """ - 根据删除规则推广到所有html - Args: - html_str: main html - post_delete_node: 删除规则 - Returns: - 处理之后的html + if not html_content: + return html_content, False + + is_success = False + tree = html_to_element(html_content) + + for remove_node in xpaths_to_remove: + xpath_content = remove_node.get('xpath') + # 获取所有元素节点 + all_elements = [element for element in tree.iter() if isinstance(element, html.HtmlElement)] + for node in tree.xpath(xpath_content): + # 获取节点内容占比 + content_rate = __calculate_node_content_ratio(tree, node) + if content_rate > 0.4: + continue + # 获取节点的位置 + node_position = __analyze_node_position(all_elements, node) + if node_position == 'middle': + continue + # 删除节点及其所有子节点 + node.getparent().remove(node) + is_success = True + + return element_to_html(tree), is_success + + +def __calculate_node_content_ratio(tree: html.HtmlElement, node: html.HtmlElement) -> float: + """计算节点内容占比. + + 参数: + tree(html.HtmlElement): 根节点对象 + node (html.HtmlElement): 节点对象 + + 返回: + float: 节点内容占比 """ - return html_str + # 获取节点的文本内容 + text_content = node.text_content() + + total_contents = tree.text_content() + content_rate = len(text_content) / len(total_contents) if total_contents else 0 + return content_rate + + +def __analyze_node_position(all_elements: List[html.HtmlElement], target_node: html.HtmlElement): + # 计算总节点数 + total_nodes = len(all_elements) + + # 新增逻辑:检查元素是否在