Minimal polynomial of 2cos(2pi/n)

In number theory, the real parts of the roots of unity are related to one-another by means of the minimal polynomial of $2\cos(2\pi /n).$ The roots of the minimal polynomial are twice the real part of the roots of unity, where the real part of a root of unity is just $\cos \left(2k\pi /n\right)$ with $k$ coprime with $n.$

Formal definition edit

For an integer $n\geq 1$ , the minimal polynomial $\Psi _{n}(x)$ of $2\cos(2\pi /n)$ is the non-zero monic polynomial of smallest degree for which $\Psi _{n}\!\left(2\cos(2\pi /n)\right)=0$ .

For every $n$ , the polynomial $\Psi _{n}(x)$ is monic, has integer coefficients, and is irreducible over the integers and the rational numbers. All its roots are real; they are the real numbers $2\cos \left(2k\pi /n\right)$ with $k$ coprime with $n$ and either $1\leq k<n$ or $k=n=1.$ These roots are twice the real parts of the primitive $n$ th roots of unity. The number of integers $k$ relatively prime to $n$ is given by Euler's totient function $\varphi (n);$ it follows that the degree of $\Psi _{n}(x)$ is $1$ for $n=1,2$ and $\varphi (n)/2$ for $n\geq 3.$

The first two polynomials are $\Psi _{1}(x)=x-2$ and $\Psi _{2}(x)=x+2.$

The polynomials $\Psi _{n}(x)$ are typical examples of irreducible polynomials whose roots are all real and which have a cyclic Galois group.

Examples edit

The first few polynomials $\Psi _{n}(x)$ are

{\begin{aligned}\Psi _{1}(x)&=x-2\\\Psi _{2}(x)&=x+2\\\Psi _{3}(x)&=x+1\\\Psi _{4}(x)&=x\\\Psi _{5}(x)&=x^{2}+x-1\\\Psi _{6}(x)&=x-1\\\Psi _{7}(x)&=x^{3}+x^{2}-2x-1\\\Psi _{8}(x)&=x^{2}-2\\\Psi _{9}(x)&=x^{3}-3x+1\\\Psi _{10}(x)&=x^{2}-x-1\\\Psi _{11}(x)&=x^{5}+x^{4}-4x^{3}-3x^{2}+3x+1\\\Psi _{12}(x)&=x^{2}-3\\\Psi _{13}(x)&=x^{6}+x^{5}-5x^{4}-4x^{3}+6x^{2}+3x-1\\\Psi _{14}(x)&=x^{3}-x^{2}-2x+1\\\Psi _{15}(x)&=x^{4}-x^{3}-4x^{2}+4x+1\\\Psi _{16}(x)&=x^{4}-4x^{2}+2\\\Psi _{17}(x)&=x^{8}+x^{7}-7x^{6}-6x^{5}+15x^{4}+10x^{3}-10x^{2}-4x+1\\\Psi _{18}(x)&=x^{3}-3x-1\\\Psi _{19}(x)&=x^{9}+x^{8}-8x^{7}-7x^{6}+21x^{5}+15x^{4}-20x^{3}-10x^{2}+5x+1\\\Psi _{20}(x)&=x^{4}-5x^{2}+5\end{aligned}}

Explicit form if n is odd edit

If $n$ is an odd prime, the polynomial $\Psi _{n}(x)$ can be written in terms of binomial coefficients following a "zigzag path" through Pascal's triangle:

Putting $n=2m+1$ and

{\begin{aligned}\chi _{n}(x):&={\binom {m}{0}}x^{m}+{\binom {m-1}{0}}x^{m-1}-{\binom {m-1}{1}}x^{m-2}-{\binom {m-2}{1}}x^{m-3}+{\binom {m-2}{2}}x^{m-4}+{\binom {m-3}{2}}x^{m-5}--++\cdots \\&=\sum _{k=0}^{m}(-1)^{\lfloor k/2\rfloor }{\binom {m-\lfloor (k+1)/2\rfloor }{\lfloor k/2\rfloor }}x^{m-k}\\&={\binom {m}{m}}x^{m}+{\binom {m-1}{m-1}}x^{m-1}-{\binom {m-1}{m-2}}x^{m-2}-{\binom {m-2}{m-3}}x^{m-3}+{\binom {m-2}{m-4}}x^{m-4}+{\binom {m-3}{m-5}}x^{m-5}--++\cdots \\&=\sum _{k=0}^{m}(-1)^{\lfloor (m-k)/2\rfloor }{\binom {\lfloor (m+k)/2\rfloor }{k}}x^{k},\end{aligned}}

then we have $\Psi _{p}(x)=\chi _{p}(x)$ for primes $p$ .

If $n$ is odd but not a prime, the same polynomial $\chi _{n}(x)$ , as can be expected, is reducible and, corresponding to the structure of the cyclotomic polynomials $\Phi _{d}(x)$ reflected by the formula $\prod _{d\mid n}\Phi _{d}(x)=x^{n}-1$ , turns out to be just the product of all $\Psi _{d}(x)$ for the divisors $d>1$ of $n$ , including $n$ itself:

\prod _{d\mid n \atop d>1}\Psi _{d}(x)=\chi _{n}(x).

This means that the $\Psi _{d}(x)$ are exactly the irreducible factors of $\chi _{n}(x)$ , which allows to easily obtain $\Psi _{d}(x)$ for any odd $d$ , knowing its degree ${\frac {1}{2}}\varphi (d)$ . For example,

{\begin{aligned}\chi _{15}(x)&=x^{7}+x^{6}-6x^{5}-5x^{4}+10x^{3}+6x^{2}-4x-1\\&=(x+1)(x^{2}+x-1)(x^{4}-x^{3}-4x^{2}+4x+1)\\&=\Psi _{3}(x)\cdot \Psi _{5}(x)\cdot \Psi _{15}(x).\end{aligned}}

Explicit form if n is even edit

From the below formula in terms of Chebyshev polynomials and the product formula for odd $n$ above, we can derive for even $n$

\prod _{d\mid n \atop d>1}\Psi _{d}(x)={\Big (}\chi _{n+1}(x)+\chi _{n-1}(x){\Big )}.

Independently of this, if $n=2^{k}$ is an even prime power, we have for $k\geq 2$ the recursion (see OEIS: A158982)

\Psi _{2^{k+1}}(x)=(\Psi _{2^{k}}(x))^{2}-2

,

starting with $\Psi _{4}(x)=x$ .

Roots edit

The roots of $\Psi _{n}(x)$ are given by $2\cos \left({\frac {2\pi k}{n}}\right)$ ,^[1] where $1\leq k<{\frac {n}{2}}$ and $\gcd(k,n)=1$ . Since $\Psi _{n}(x)$ is monic, we have

\Psi _{n}(x)=\displaystyle \prod _{\begin{array}{c}1\leq k<{\frac {n}{2}}\\\gcd(k,n)=1\end{array}}\left(x-2\cos \left({\frac {2\pi k}{n}}\right)\right).

Combining this result with the fact that the function $\cos(x)$ is even, we find that $2\cos \left({\frac {2\pi k}{n}}\right)$ is an algebraic integer for any positive integer $n$ and any integer $k$ .

Relation to the cyclotomic polynomials edit

For a positive integer $n$ , let $\zeta _{n}=\exp \left({\frac {2\pi i}{n}}\right)=\cos \left({\frac {2\pi }{n}}\right)+\sin \left({\frac {2\pi }{n}}\right)i$ , a primitive $n$ -th root of unity. Then the minimal polynomial of $\zeta _{n}$ is given by the $n$ -th cyclotomic polynomial $\Phi _{n}(x)$ . Since $\zeta _{n}^{-1}=\cos \left({\frac {2\pi }{n}}\right)-\sin \left({\frac {2\pi }{n}}\right)i$ , the relation between $2\cos \left({\frac {2\pi }{n}}\right)$ and $\zeta _{n}$ is given by $2\cos \left({\frac {2\pi }{n}}\right)=\zeta _{n}+\zeta _{n}^{-1}$ . This relation can be exhibited in the following identity proved by Lehmer, which holds for any non-zero complex number $z$ :^[2]

\Psi _{n}\left(z+z^{-1}\right)=z^{-{\frac {\varphi (n)}{2}}}\Phi _{n}(z)

Relation to Chebyshev polynomials edit

In 1993, Watkins and Zeitlin established the following relation between $\Psi _{n}(x)$ and Chebyshev polynomials of the first kind.^[1]

If $n=2s+1$ is odd, then^{[verification needed]}

\prod _{d\mid n}\Psi _{d}(2x)=2(T_{s+1}(x)-T_{s}(x)),

and if $n=2s$ is even, then

\prod _{d\mid n}\Psi _{d}(2x)=2(T_{s+1}(x)-T_{s-1}(x)).

If $n$ is a power of $2$ , we have moreover directly^[3]

\Psi _{2^{k+1}}(2x)=2T_{2^{k-1}}(x).

Absolute value of the constant coefficient edit

The absolute value of the constant coefficient of $\Psi _{n}(x)$ can be determined as follows:^[4]

|\Psi _{n}(0)|={\begin{cases}0&{\text{if}}\ n=4,\\2&{\text{if}}\ n=2^{k},k\geq 0,k\neq 2,\\p&{\text{if}}\ n=4p^{k},k\geq 1,p>2\ {\text{prime,}}\\1&{\text{otherwise.}}\end{cases}}

Generated algebraic number field edit

The algebraic number field $K_{n}=\mathbb {Q} \left(\zeta _{n}+\zeta _{n}^{-1}\right)$ is the maximal real subfield of a cyclotomic field $\mathbb {Q} (\zeta _{n})$ . If ${\mathcal {O}}_{K_{n}}$ denotes the ring of integers of $K_{n}$ , then ${\mathcal {O}}_{K_{n}}=\mathbb {Z} \left[\zeta _{n}+\zeta _{n}^{-1}\right]$ . In other words, the set $\left\{1,\zeta _{n}+\zeta _{n}^{-1},\ldots ,\left(\zeta _{n}+\zeta _{n}^{-1}\right)^{{\frac {\varphi (n)}{2}}-1}\right\}$ is an integral basis of ${\mathcal {O}}_{K_{n}}$ . In view of this, the discriminant of the algebraic number field $K_{n}$ is equal to the discriminant of the polynomial $\Psi _{n}(x)$ , that is^[5]