Unit roots/Properties of unit roots

In this chapter, we will look at the basic properties of the root of unity.

An example[edit | edit source]

Example 1 It is given ${\displaystyle a^{2}+a+1=0}$, prove that

${\displaystyle a^{2012}+({\frac {1}{a}})^{2012}=a^{1987}+({\frac {1}{a}})^{1987}}$.

Prove From the given equation, we can show that ${\displaystyle a^{3}=1}$:

${\displaystyle a^{3}=a^{3}-1+1=(a-1)(a^{2}+a+1)+1=1}$.

Therefore,

${\displaystyle a^{2012}=a^{670\times 3+2}=(a^{3})^{670}+a^{2}=a^{2}}$

${\displaystyle ({\frac {1}{a}})^{2012}=a^{-671\times 3+1}=(a^{3})^{-671}+a=a}$

${\displaystyle a^{1987}=a^{662\times 3+1}=(a^{3})^{662}+a=a}$

${\displaystyle ({\frac {1}{a}})^{1987}=a^{-663\times 3+2}=(a^{3})^{-663}+a^{2}=a^{2}}$

So, both sides of the equation equal ${\displaystyle a^{2}+a}$. QED

Moreover, we can calculate the value of each side: ${\displaystyle a^{2}+a=a^{2}+a+1-1=-1}$.

In fact, we can obtain a more general result:

Example 2 Given ${\displaystyle a^{2}+a+1=0}$, and ${\displaystyle n}$ is a natural number. Evaluate ${\displaystyle a^{n}+({\frac {1}{a}})^{n}}$.

Solution

${\displaystyle a^{n}+({\frac {1}{a}})^{n}={\begin{cases}-1&{\text{if }}n{\text{ is not a multiple of 3}}\\2&{\text{if }}n{\text{ is a multiple of 3}}\end{cases}}}$

The roots of unity[edit | edit source]

We have make use of an important observation, namely ${\displaystyle a^{3}=1}$, in the examples above. Numbers that satisfy the equation:

${\displaystyle a^{n}=1,\quad n{\text{ is a natural number}}}$

are called the nth roots of unity or the unit roots. From the knowledge of algebra, the following formula:

${\displaystyle \epsilon _{k}=\cos {\frac {2k\pi }{n}}+i\sin {\frac {2k\pi }{n}},\quad k{\text{ is a natural number}}}$

always gives a root of unity. When ${\displaystyle k=0,1,\ldots ,n-1}$, ${\displaystyle \epsilon _{k}}$ takes distinct values, and when ${\displaystyle k}$ takes other values, ${\displaystyle \epsilon _{k}}$ equals one of the values ${\displaystyle \epsilon _{0},\epsilon _{1},\ldots ,\epsilon _{n-1}}$. Moreover, as a polynomial equation of degree ${\displaystyle n}$, the equation has exactly ${\displaystyle n}$ roots. Therefore, ALL roots of unity are:

${\displaystyle \epsilon _{0},\epsilon _{1},\ldots ,\epsilon _{n-1}}$.

Note that ${\displaystyle \epsilon _{0}=1}$.

On the other hand, the roots of unity are the solution of the equation:

${\displaystyle x^{n}-1=0}$.

Moreover:

${\displaystyle x^{n}-1=(x-1)(x^{n-1}+x^{n-2}+\cdots +x+1)}$.

Therefore, ${\displaystyle \epsilon _{1},\epsilon _{2},\ldots ,\epsilon _{n-1}}$ are all roots of the equation:

${\displaystyle x^{n-1}+x^{n-2}+\cdots +x+1=0}$.

The cube roots of unity[edit | edit source]

The cube roots of unity is a good starting point in our study of the properties of unit roots.

Example 3 The cube roots of unity are:

${\displaystyle \epsilon _{0}=1}$,

${\displaystyle \epsilon _{1}=\cos {\frac {2\pi }{3}}+i\sin {\frac {2\pi }{3}}=-{\frac {1}{2}}+{\frac {\sqrt {3}}{2}}i}$,

${\displaystyle \epsilon _{2}=\cos {\frac {4\pi }{3}}+i\sin {\frac {4\pi }{3}}=-{\frac {1}{2}}-{\frac {\sqrt {3}}{2}}i}$.

We usually write ${\displaystyle \omega =\epsilon _{1}}$. Then:

${\displaystyle \omega ^{2}=(-{\frac {1}{2}}+{\frac {\sqrt {3}}{2}}i)^{2}={\frac {1}{4}}-{\frac {\sqrt {3}}{2}}i-{\frac {3}{4}}=-{\frac {1}{2}}-{\frac {\sqrt {3}}{2}}i=\epsilon _{2}}$.

Therefore, the cube roots of unity can also be written as ${\displaystyle 1,\omega ,\omega ^{2}}$. The cube root of unity has the following properties:

1. They have a unit modulus: ${\displaystyle |1|=|\omega |=|\omega ^{2}|=1}$.
2. ${\displaystyle 1,\omega ,\omega ^{2}}$ are the roots of the equation ${\displaystyle x^{3}-1=0}$.
3. ${\displaystyle \omega ,\omega ^{2}}$ are the roots of the equation ${\displaystyle x^{2}+x+1=0}$.
4. ${\displaystyle \epsilon _{2}^{2}=(-{\frac {1}{2}}-{\frac {\sqrt {3}}{2}}i)^{2}={\frac {1}{4}}+{\frac {\sqrt {3}}{2}}i-{\frac {3}{4}}=-{\frac {1}{2}}+{\frac {\sqrt {3}}{2}}i=\epsilon _{1}}$. So, the cube roots of unity still have the form of ${\displaystyle 1,\omega ,\omega ^{2}}$ if we let ${\displaystyle \omega =\epsilon _{2}}$.
5. On the complex plane, the roots of unity are at the vertices of the regular triangle inscribed in the unit circle, with one vertex at 1.
6. ${\displaystyle {\overline {\omega }}=\omega ^{2}}$, ${\displaystyle {\overline {\omega ^{2}}}=\omega }$.
7. ${\displaystyle 1^{n}+\omega ^{n}+(\omega ^{2})^{n}={\begin{cases}0&{\text{if }}n{\text{ is not a multiple of 3}}\\3&{\text{if }}n{\text{ is a multiple of 3}}\end{cases}}}$

General properties of roots of unity[edit | edit source]

After looking at the properties of the cube roots of unity, we are ready to study the general properties of the nth roots of unity.

Property 1 The nth roots of unity have a unit modulus, that is:

${\displaystyle |\epsilon _{k}|=1\quad k{\text{ is an integer}}}$.

Proof It follows from the polar form of the unit roots.

Property 2 The product of two unit roots is also a unit root. Specifically, if ${\displaystyle j}$ and ${\displaystyle k}$ are integers, then:

${\displaystyle \epsilon _{j}\cdot \epsilon _{k}=\epsilon _{j+k}}$.

Proof From the multiplication rule of complex number:

${\displaystyle \epsilon _{j}\cdot \epsilon _{k}=(\cos {\frac {2j\pi }{n}}+i\sin {\frac {2j\pi }{n}})\cdot (\cos {\frac {2k\pi }{n}}+i\sin {\frac {2k\pi }{n}})=(\cos {\frac {2(j+k)\pi }{n}}+i\sin {\frac {2(j+k)\pi }{n}})=\epsilon _{j+k}}$.

This is a very important property of the roots of unity, from which a series of corollary can be derived:

Corollary 1 ${\displaystyle (\epsilon _{j})^{-1}=\epsilon _{-j}}$.
Proof ${\displaystyle \epsilon _{j}\cdot \epsilon _{-j}=\epsilon _{j+(-j)}=\epsilon _{0}=1}$. Now, since ${\displaystyle \epsilon _{j}\neq 0}$, multiplying its inverse on both sides yields ${\displaystyle (\epsilon _{j})^{-1}=\epsilon _{-j}}$.

Corollary 2 For any integer ${\displaystyle m}$:

${\displaystyle (\epsilon _{k})^{m}=\epsilon _{mk}}$.

Proof When ${\displaystyle m}$ is positive, ${\displaystyle (\epsilon _{k})^{m}=\underbrace {\epsilon _{k}\cdot \epsilon _{k}\cdot \cdots \cdot \epsilon _{k}} _{m{\text{ times}}}=\epsilon _{\underbrace {{}_{k+k+\cdots +k}} _{m{\text{ times}}}}=\epsilon _{mk}}$.
When ${\displaystyle m=0}$, non-zero complex number raised to the power of 0 is 1, so ${\displaystyle (\epsilon _{k})^{0}=1=\epsilon _{0}}$.
When ${\displaystyle m}$ is negative, ${\displaystyle -m}$ is positive, so ${\displaystyle (\epsilon _{j})^{m}=((\epsilon _{j})^{-m})^{-1}=(\epsilon _{-mj})^{-1}=\epsilon _{mj}}$.

Corollary 3 If ${\displaystyle r}$ is the remainder when ${\displaystyle k}$ is divided by ${\displaystyle n}$, then ${\displaystyle \epsilon _{k}=\epsilon _{r}}$.
Proof Let ${\displaystyle k=nq+r}$ where ${\displaystyle q}$ is an integer and ${\displaystyle 0\leq r<n}$, then:

${\displaystyle \epsilon _{k}=\epsilon _{nq+r}=(\epsilon _{n})^{q}\cdot \epsilon _{r}=1^{n}\epsilon _{r}=\epsilon _{r}}$.

Corollary 4 ${\displaystyle \epsilon _{k}=(\epsilon _{1})^{k}}$.
Any root of unity can be expressed as a power of ${\displaystyle \epsilon _{1}}$.

We may ask the following question: is there any other root of unity ${\displaystyle \epsilon _{\ell }}$ such that any root of unity can be expressed as a power of ${\displaystyle \epsilon _{\ell }}$?

In fact we have seen such an example when we studied the cube root of unity. A unit root with such property is called a primitive root.

Corollary 5 The conjugate of a unit root is also a unit root.
Proof From the property of complex numbers ${\displaystyle z\cdot {\overline {z}}=|z|^{2}}$ and ${\displaystyle |\epsilon _{k}|=1}$, ${\displaystyle {\overline {\epsilon _{k}}}={\frac {|\epsilon _{k}|^{2}}{\epsilon _{k}}}={\frac {1}{\epsilon _{k}}}=\epsilon _{-k}=\epsilon _{n-k}}$

Corollary 6 ${\displaystyle (\epsilon _{k})^{j}=(\epsilon _{j})^{k}}$.
Proof ${\displaystyle (\epsilon _{k})^{j}=\epsilon _{jk}=(\epsilon _{j})^{k}}$.

Property 3 Let ${\displaystyle m}$ be an integer, then:

${\displaystyle 1+\epsilon _{1}^{m}+\epsilon _{2}^{m}+\cdots +\epsilon _{n-1}^{m}={\begin{cases}0&{\text{if }}m{\text{ is not a multiple of }}n\\n&{\text{if }}m{\text{ is a multiple of }}n\end{cases}}}$

Proof When ${\displaystyle m}$ is a multiple of ${\displaystyle n}$, ${\displaystyle (\epsilon _{k})^{m}=1}$ for any integer ${\displaystyle k}$, so:

${\displaystyle 1+\epsilon _{1}^{m}+\epsilon _{2}^{m}+\cdots +\epsilon _{n-1}^{m}=\overbrace {1+1+\cdots +1} ^{n{\text{ times}}}=n}$

When ${\displaystyle m}$ is not a multiple of ${\displaystyle n}$, ${\displaystyle (\epsilon _{1})^{m}\neq 1}$. Then:

${\displaystyle 1+\epsilon _{1}^{m}+\epsilon _{2}^{m}+\cdots +\epsilon _{n-1}^{m}=1+\epsilon _{m}+(\epsilon _{m})^{2}+\cdots +(\epsilon _{m})^{n-1}={\frac {1-(\epsilon _{m})^{n}}{1-\epsilon _{m}}}={\frac {1-(\epsilon _{n})^{m}}{1-\epsilon _{m}}}={\frac {1-1}{1-\epsilon _{m}}}=0}$.

Corollary 7 If ${\displaystyle n>1}$, the sum of all unit roots is zero: ${\displaystyle 1+\epsilon _{1}+\epsilon _{2}+\cdots +\epsilon _{n-1}=0}$.
Proof Take ${\displaystyle m=1}$. Alternatively, the sum of roots of the equation ${\displaystyle x^{n}-1=0}$ is zero.

Corollary 8 If ${\displaystyle n>1}$ and ${\displaystyle \epsilon _{k}\neq 1}$, then ${\displaystyle 1+\epsilon _{k}+(\epsilon _{k})^{2}+\cdot +(\epsilon _{k})^{n-1}=0}$.
Proof Since ${\displaystyle \epsilon _{k}\neq 1=\epsilon _{0}}$, ${\displaystyle k}$ is not a multiple of ${\displaystyle n}$. Then:

${\displaystyle 1+\epsilon _{k}+(\epsilon _{k})^{2}+\cdots +(\epsilon _{k})^{n-1}=1+(\epsilon _{1})^{k}+(\epsilon _{2})^{k}+\cdots +(\epsilon _{n-1})^{k}=0}$.

Therefore, if we exclude ${\displaystyle \epsilon _{0}=1}$, the nth roots of unity ${\displaystyle \epsilon _{1},\epsilon _{2},\ldots ,\epsilon _{n-1}}$ are the roots of the equation:

${\displaystyle 1+x+x^{2}+\cdots +x^{n-1}=0}$.

Examples[edit | edit source]

Example 4 Find the fifth roots of unity.
Solution It can be proved that:

${\displaystyle \cos {\frac {2\pi }{5}}={\frac {{\sqrt {5}}-1}{4}}}$,

${\displaystyle \sin {\frac {2\pi }{5}}={\frac {\sqrt {10+2{\sqrt {5}}}}{4}}}$.

Therefore,

${\displaystyle \epsilon _{0}=1}$,

${\displaystyle \epsilon _{1}={\frac {{\sqrt {5}}-1}{4}}+{\frac {\sqrt {10+2{\sqrt {5}}}}{4}}i}$,

by corollary 4 of property 2,

${\displaystyle \epsilon _{2}=({\frac {{\sqrt {5}}-1}{4}}+{\frac {\sqrt {10+2{\sqrt {5}}}}{4}}i)^{2}=-{\frac {{\sqrt {5}}+1}{4}}+{\frac {\sqrt {10-2{\sqrt {5}}}}{4}}i}$,

by corollary 5 of property 2,

${\displaystyle \epsilon _{3}={\overline {\epsilon _{2}}}=-{\frac {{\sqrt {5}}+1}{4}}-{\frac {\sqrt {10-2{\sqrt {5}}}}{4}}i}$,

${\displaystyle \epsilon _{4}={\overline {\epsilon _{1}}}={\frac {{\sqrt {5}}-1}{4}}-{\frac {\sqrt {10+2{\sqrt {5}}}}{4}}i}$.

Example 5 Find the sixth roots of unity in terms of ${\displaystyle \omega }$.
Solution

${\displaystyle \epsilon _{0}=1}$,

${\displaystyle \epsilon _{1}=\cos {\frac {2\pi }{6}}+i\sin {\frac {2\pi }{6}}={\frac {1}{2}}+{\frac {\sqrt {3}}{2}}i=1+\omega }$,

${\displaystyle \epsilon _{2}=\cos {\frac {4\pi }{6}}+i\sin {\frac {4\pi }{6}}=-{\frac {1}{2}}+{\frac {\sqrt {3}}{2}}i=\omega }$,

${\displaystyle \epsilon _{3}=\cos {\frac {6\pi }{6}}+i\sin {\frac {6\pi }{6}}=-1}$,

${\displaystyle \epsilon _{4}=\cos {\frac {8\pi }{6}}+i\sin {\frac {8\pi }{6}}=-{\frac {1}{2}}-{\frac {\sqrt {3}}{2}}i=\omega ^{2}}$,

${\displaystyle \epsilon _{5}=\cos {\frac {10\pi }{6}}+i\sin {\frac {10\pi }{6}}={\frac {1}{2}}-{\frac {\sqrt {3}}{2}}i=1+\omega ^{2}}$.

Example 6 Evaluate:

${\displaystyle {\tbinom {0}{n}}+{\tbinom {3}{n}}+{\tbinom {6}{n}}+{\tbinom {9}{n}}+\cdots +{\tbinom {3\ell -3}{n}}+{\tbinom {3\ell }{n}}}$,

where ${\displaystyle 3\ell }$ is the greatest multiple of 3 not exceeding ${\displaystyle n}$.
Analysis The expression is the sum of every first of three consecutive binomial coefficients:

${\displaystyle {\tbinom {0}{n}},{\tbinom {1}{n}},{\tbinom {2}{n}},{\tbinom {3}{n}},\ldots ,{\tbinom {n-1}{n}},{\tbinom {n}{n}}}$.

A similar but more familiar sum is:

${\displaystyle {\tbinom {0}{n}}+{\tbinom {2}{n}}+{\tbinom {4}{n}}+\cdots }$,

which can be computed by summing the binomial expansions:

${\displaystyle (1+x)^{n}={\tbinom {0}{n}}+{\tbinom {1}{n}}x+{\tbinom {2}{n}}x^{2}+\cdots +{\tbinom {n}{n}}x^{n}}$

for ${\displaystyle x=+1,-1}$ (note that these are the square root of unity). The sum is

${\displaystyle (1+1)^{n}+(1-1)^{n}=2{\tbinom {0}{n}}+(1+(-1)){\tbinom {1}{n}}+(1^{2}+(-1)^{2})){\tbinom {2}{n}}+\cdots +(1^{n}+(-1)^{n}){\tbinom {n}{n}}}$.

The value ${\displaystyle 1^{k}+(-1)^{k}}$(the coefficient of ${\displaystyle {\tbinom {k}{n}}}$) equals zero when ${\displaystyle k}$ is odd, but equals two when ${\displaystyle k}$ is even. (Note also that this follows from Property 3 for the square roots of unity.) Therefore,

${\displaystyle 2{\tbinom {0}{n}}+2{\tbinom {2}{n}}+2{\tbinom {4}{n}}+\cdots =2^{n}}$

${\displaystyle {\tbinom {0}{n}}+{\tbinom {2}{n}}+{\tbinom {4}{n}}+\cdots =2^{n-1}}$

For the sum in this example, property 3 for the cube roots of unity may be useful.
Solution Summing the binomial expansions:

${\displaystyle (1+x)^{n}={\tbinom {0}{n}}+{\tbinom {1}{n}}x+{\tbinom {2}{n}}x^{2}+\cdots +{\tbinom {n}{n}}x^{n}}$

for ${\displaystyle x=1,\omega ,\omega ^{2}}$ yields

${\displaystyle (1+1)^{n}+(1+\omega )^{n}+(1+\omega ^{2})^{n}=3{\tbinom {0}{n}}+(1+\omega +\omega ^{2}){\tbinom {1}{n}}+(1^{2}+\omega ^{2}+(\omega ^{2})^{2}){\tbinom {2}{n}}+\cdots +(1^{n}+\omega ^{n}+(\omega ^{2})^{n}){\tbinom {n}{n}}}$.

By property 3, the coefficient of every first of three terms equals 3 and all other terms vanish. Therefore,

${\displaystyle 3{\tbinom {0}{n}}+3{\tbinom {3}{n}}+3{\tbinom {6}{n}}+\cdots =2^{n}+(-\omega ^{2})^{n}+(-\omega )^{n}}$

${\displaystyle =2^{n}+(\cos {\frac {\pi }{3}}+i\sin {\frac {\pi }{3}})^{n}+(\cos {\frac {-\pi }{3}}+i\sin {\frac {-\pi }{3}})^{n}}$

${\displaystyle =2^{n}+2\cos {\frac {n\pi }{3}}}$

${\displaystyle {\tbinom {0}{n}}+{\tbinom {3}{n}}+{\tbinom {6}{n}}+{\tbinom {9}{n}}+\cdots +{\tbinom {3\ell -3}{n}}+{\tbinom {3\ell }{n}}={\frac {1}{3}}(2^{n}+2\cos {\frac {n\pi }{3}})}$.