De Moivre's formula

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In mathematics, de Moivre's formula (also known as de Moivre's theorem and de Moivre's identity) states that for any real number Template:Mvar and integer Template:Mvar it is the case that $${\displaystyle (\cos x+i\sin x{)}^n=\cos nx+i\sin nx,}$$ where Template:Mvar is the imaginary unit (Template:Math). The formula is named after Abraham de Moivre,^[1] although he never stated it in his works.^[2] The expression Template:Math is sometimes abbreviated to Template:Math.

The formula is important because it connects complex numbers and trigonometry. By expanding the left hand side and then comparing the real and imaginary parts under the assumption that Template:Mvar is real, it is possible to derive useful expressions for Template:Math and Template:Math in terms of Template:Math and Template:Math.

As written, the formula is not valid for non-integer powers Template:Mvar. However, there are generalizations of this formula valid for other exponents. These can be used to give explicit expressions for the Template:Mvarth roots of unity, that is, complex numbers Template:Mvar such that Template:Math.

Using the standard extensions of the sine and cosine functions to complex numbers, the formula is valid even when Template:Mvar is an arbitrary complex number.

For ${\displaystyle x=30^{\circ }}$ and ${\displaystyle n=2}$, de Moivre's formula asserts that $${\displaystyle {(\cos (30^{\circ })+i\sin (30^{\circ }))}^2=\cos (2\cdot 30^{\circ })+i\sin (2\cdot 30^{\circ }),}$$ or equivalently that $${\displaystyle {(\frac{\sqrt{3}}{2}+\frac{i}{2})}^2=\frac{1}{2}+\frac{i\sqrt{3}}{2}.}$$ In this example, it is easy to check the validity of the equation by multiplying out the left side.

De Moivre's formula is a precursor to Euler's formula $${\displaystyle e^{ix}=\cos x+i\sin x,}$$ with Template:Mvar expressed in radians rather than degrees, which establishes the fundamental relationship between the trigonometric functions and the complex exponential function.

One can derive de Moivre's formula using Euler's formula and the exponential law for integer powers

${\displaystyle {\left(e^{ix}\right)}^n=e^{inx},}$

since Euler's formula implies that the left side is equal to ${\displaystyle {(\cos x+i\sin x)}^n}$ while the right side is equal to ${\displaystyle \cos nx+i\sin nx.}$

The truth of de Moivre's theorem can be established by using mathematical induction for natural numbers, and extended to all integers from there. For an integer Template:Mvar, call the following statement Template:Math:

${\displaystyle (\cos x+i\sin x{)}^n=\cos nx+i\sin nx.}$

For Template:Math, we proceed by mathematical induction. Template:Math is clearly true. For our hypothesis, we assume Template:Math is true for some natural Template:Mvar. That is, we assume

${\displaystyle {(\cos x+i\sin x)}^k=\cos kx+i\sin kx.}$

Now, considering Template:Math:

${\displaystyle \begin{array}{cc}{(\cos x+i\sin x)}^{k+1}& ={(\cos x+i\sin x)}^k(\cos x+i\sin x)\\ & =(\cos kx+i\sin kx)(\cos x+i\sin x)& & \text{by the induction hypothesis}\\ & =\cos kx\cos x-\sin kx\sin x+i(\cos kx\sin x+\sin kx\cos x)\\ & =\cos ((k+1)x)+i\sin ((k+1)x)& & \text{by the trigonometric identities}\end{array}}$

See angle sum and difference identities.

We deduce that Template:Math implies Template:Math. By the principle of mathematical induction it follows that the result is true for all natural numbers. Now, Template:Math is clearly true since Template:Math. Finally, for the negative integer cases, we consider an exponent of Template:Math for natural Template:Mvar.

${\displaystyle \begin{array}{cc}{(\cos x+i\sin x)}^{-n}& =({(\cos x+i\sin x)}^n{)}^{-1}\\ & ={(\cos nx+i\sin nx)}^{-1}\\ & =\cos nx-i\sin nx(*)\\ & =\cos (-nx)+i\sin (-nx).\\ \end{array}}$

The equation (*) is a result of the identity

${\displaystyle z^{-1}=\frac{\overline{z}}{|z{|}^2},}$

for Template:Math. Hence, Template:Math holds for all integers Template:Mvar.

Template:See also For an equality of complex numbers, one necessarily has equality both of the real parts and of the imaginary parts of both members of the equation. If Template:Mvar, and therefore also Template:Math and Template:Math, are real numbers, then the identity of these parts can be written using binomial coefficients. This formula was given by 16th century French mathematician François Viète:

${\displaystyle \begin{array}{cc}\sin nx& ={\displaystyle \sum _{k=0}^n}{\displaystyle (\genfrac{}{}{0ex}{}{n}{k})}(\cos x{)}^k(\sin x{)}^{n-k}\sin \frac{(n-k)\pi }{2}\\ \cos nx& ={\displaystyle \sum _{k=0}^n}{\displaystyle (\genfrac{}{}{0ex}{}{n}{k})}(\cos x{)}^k(\sin x{)}^{n-k}\cos \frac{(n-k)\pi }{2}.\end{array}}$

In each of these two equations, the final trigonometric function equals one or minus one or zero, thus removing half the entries in each of the sums. These equations are in fact valid even for complex values of Template:Mvar, because both sides are entire (that is, holomorphic on the whole complex plane) functions of Template:Mvar, and two such functions that coincide on the real axis necessarily coincide everywhere. Here are the concrete instances of these equations for Template:Math and Template:Math:

${\displaystyle \begin{array}{cccc}\cos 2x& ={(\cos x)}^2+({(\cos x)}^2-1)& =& 2{(\cos x)}^2-1\\ \sin 2x& =2(\sin x)(\cos x)& & \\ \cos 3x& ={(\cos x)}^3+3\cos x({(\cos x)}^2-1)& =& 4{(\cos x)}^3-3\cos x\\ \sin 3x& =3{(\cos x)}^2(\sin x)-{(\sin x)}^3& =& 3\sin x-4{(\sin x)}^3.\end{array}}$

The right-hand side of the formula for Template:Math is in fact the value Template:Math of the Chebyshev polynomial Template:Math at Template:Math.

De Moivre's formula does not hold for non-integer powers. The derivation of de Moivre's formula above involves a complex number raised to the integer power Template:Mvar. If a complex number is raised to a non-integer power, the result is multiple-valued (see failure of power and logarithm identities).

A modest extension of the version of de Moivre's formula given in this article can be used to find [[nth root|the Template:Mvar-th roots]] of a complex number for a non-zero integer Template:Mvar. (This is equivalent to raising to a power of Template:Math).

If Template:Mvar is a complex number, written in polar form as

${\displaystyle z=r(\cos x+i\sin x),}$

then the Template:Mvar-th roots of Template:Mvar are given by

${\displaystyle r^{\frac{1}{n}}(\cos \frac{x+2\pi k}{n}+i\sin \frac{x+2\pi k}{n})}$

where Template:Mvar varies over the integer values from 0 to Template:Math.

This formula is also sometimes known as de Moivre's formula.^[3]

Generally, if ${\displaystyle z=r(\cos x+i\sin x)}$ (in polar form) and Template:Mvar are arbitrary complex numbers, then the set of possible values is $${\displaystyle z^w=r^w{(\cos x+i\sin x)}^w=\{r^w\cos (xw+2\pi kw)+i{r}^w\sin (xw+2\pi kw)|k\in \mathbb{Z}\}.}$$ (Note that if Template:Mvar is a rational number that equals Template:Math in lowest terms then this set will have exactly Template:Mvar distinct values rather than infinitely many. In particular, if Template:Mvar is an integer then the set will have exactly one value, as previously discussed.) In contrast, de Moivre's formula gives $${\displaystyle r^w(\cos xw+i\sin xw),}$$ which is just the single value from this set corresponding to Template:Math.

Since Template:Math, an analog to de Moivre's formula also applies to the hyperbolic trigonometry. For all integers Template:Mvar,

${\displaystyle (\cosh x+\sinh x{)}^n=\cosh nx+\sinh nx.}$

If Template:Mvar is a rational number (but not necessarily an integer), then Template:Math will be one of the values of Template:Math.^[4]

For any integer Template:Mvar, the formula holds for any complex number ${\displaystyle z=x+iy}$

${\displaystyle (\cos z+i\sin z{)}^n=\cos nz+i\sin nz.}$

where

${\displaystyle \begin{array}{cc}\cos z=\cos (x+iy)& =\cos x\cosh y-i\sin x\sinh y,\\ \sin z=\sin (x+iy)& =\sin x\cosh y+i\cos x\sinh y.\end{array}}$

To find the roots of a quaternion there is an analogous form of de Moivre's formula. A quaternion in the form

${\displaystyle q=d+a\widehat{𝐢}+b\widehat{𝐣}+c\widehat{𝐤}}$

can be represented in the form

${\displaystyle q=k(\cos \theta +\epsilon \sin \theta )\text{for }0\le \theta <2\pi .}$

In this representation,

${\displaystyle k=\sqrt{d^2+a^2+b^2+c^2},}$

and the trigonometric functions are defined as

${\displaystyle \cos \theta =\frac{d}{k}\text{and}\sin \theta =\pm \frac{\sqrt{a^2+b^2+c^2}}{k}.}$

In the case that Template:Math,

${\displaystyle \epsilon =\pm \frac{a\widehat{𝐢}+b\widehat{𝐣}+c\widehat{𝐤}}{\sqrt{a^2+b^2+c^2}},}$

that is, the unit vector. This leads to the variation of De Moivre's formula:

${\displaystyle q^n=k^n(\cos n\theta +\epsilon \sin n\theta ).}$^[5]

To find the cube roots of

${\displaystyle Q=1+\widehat{𝐢}+\widehat{𝐣}+\widehat{𝐤},}$

write the quaternion in the form

${\displaystyle Q=2(\cos \frac{\pi }{3}+\epsilon \sin \frac{\pi }{3})\text{where }\epsilon =\frac{\widehat{𝐢}+\widehat{𝐣}+\widehat{𝐤}}{\sqrt{3}}.}$

Then the cube roots are given by:

${\displaystyle \sqrt[3]{Q}=\sqrt[3]{2}(\cos \theta +\epsilon \sin \theta )\text{for }\theta =\frac{\pi }{9},\frac{7\pi }{9},\frac{13\pi }{9}.}$

With matrices, ${\displaystyle {\left(\begin{array}{cc}\cos \varphi & -\sin \varphi \\ \sin \varphi & \cos \varphi \end{array}\right)}^n=\left(\begin{array}{cc}\cos n\varphi & -\sin n\varphi \\ \sin n\varphi & \cos n\varphi \end{array}\right)}$ when Template:Mvar is an integer. This is a direct consequence of the isomorphism between the matrices of type ${\displaystyle \left(\begin{array}{cc}a& -b\\ b& a\end{array}\right)}$ and the complex plane.

• Template:Cite book.

Template:Reflist

• De Moivre's Theorem for Trig Identities by Michael Croucher, Wolfram Demonstrations Project.

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