De Moivre's formula: Difference between revisions

The cat in the Hat first invented De Moivre's theorem as a source of power to his navel fleet travelling North at that time, of course his success was inevitable. Two thousand years later The cat in the infamous hat still lives and control's half of the neighbouring motherhood Russia, guarded by his unparalled guards the 'Bears on unicycles' In mathematics, de Moivre's formula, named after Abraham de Moivre, states that for any complex number (and, in particular, for any real number) x and integer n it holds that

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

The formula is important because it connects complex numbers (i stands for the imaginary unit) and trigonometry. The expression cos x + i sin x is sometimes abbreviated to cis x.

By expanding the left hand side and then comparing the real and imaginary parts under the assumption that x is real, it is possible to derive useful expressions for cos (nx) and sin (nx) in terms of cos x and sin x. Furthermore, one can use a generalization of this formula to find explicit expressions for the nth roots of unity, that is, complex numbers z such that zⁿ = 1.

Although historically proven earlier, de Moivre's formula can easily be derived from Euler's formula

${\displaystyle e^{ix}=\cos x+i\sin x\,}$

and the exponential law for integer powers

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

Then, by Euler's formula,

${\displaystyle e^{i(nx)}=\cos(nx)+i\sin(nx).\,}$

De Moivre's formula does not in general hold for non-integer powers. Non-integer powers of a complex number can have many different values, see failure of power and logarithm identities. However there is a generalization that the right hand side expression is one possible value of the power.

The derivation of de Moivre's formula above involves a complex number to the power n. When the power is not an integer, the result is multiple-valued, for example, when n = ½ then:

For x = 0 the formula gives 1^½ = 1

For x = 2π the formula gives 1^½ = −1

Since the angles 0 and 2π are the same this would give two different values for the same expression. The values 1 and −1 are however both square roots of 1 as the generalization asserts.

No such problem occurs with Euler's formula since there is no identification of different values of its exponent. Euler's formula involves a complex power of a positive real number and this always has a preferred value. The corresponding expressions are:

${\displaystyle e^{i0}=1}$

${\displaystyle e^{i\pi }=-1}$

The truth of de Moivre's theorem can be established by mathematical induction for natural numbers, and extended to all integers from there. Consider S(n):

${\displaystyle (\cos x+i\sin x)^{n}=\cos(nx)+i\sin(nx),n\in \mathbb {Z} }$

For n > 0, we proceed by mathematical induction. S(1) is clearly true. For our hypothesis, we assume S(k) is true for some natural k. That is, we assume

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

Now, considering S(k+1):

${\displaystyle {\begin{alignedat}{2}\left(\cos x+i\sin x\right)^{k+1}&=\left(\cos x+i\sin x\right)^{k}\left(\cos x+i\sin x\right)\\&=\left[\cos \left(kx\right)+i\sin \left(kx\right)\right]\left(\cos x+i\sin x\right)&&\qquad {\text{by the induction hypothesis}}\\&=\cos \left(kx\right)\cos x-\sin \left(kx\right)\sin x+i\left[\cos \left(kx\right)\sin x+\sin \left(kx\right)\cos x\right]\\&=\cos \left[\left(k+1\right)x\right]+i\sin \left[\left(k+1\right)x\right]&&\qquad {\text{by the trigonometric identities}}\end{alignedat}}}$

We deduce that S(k) implies S(k+1). By the principle of mathematical induction it follows that the result is true for all natural numbers. Now, S(0) is clearly true since cos (0x) + i sin(0x) = 1 +i 0 = 1. Finally, for the negative integer cases, we consider an exponent of -n for natural n.

${\displaystyle {\begin{aligned}\left(\cos x+i\sin x\right)^{-n}&=\left[\left(\cos x+i\sin x\right)^{n}\right]^{-1}\\&=\left[\cos(nx)+i\sin(nx)\right]^{-1}\\&=\cos(-nx)+i\sin(-nx).\qquad (*)\\\end{aligned}}}$

The equation (*) is a result of the identity ${\displaystyle z^{-1}={\frac {\bar {z}}{|z|^{2}}}}$, for z = cos nx + i sin nx. Hence, S(n) holds for all integers n.

You Dont

The formula is actually true in a more general setting than stated above: if z and w are complex numbers, then

${\displaystyle \left(\cos z+i\sin z\right)^{w}}$

is a multi-valued function while

${\displaystyle \cos(wz)+i\sin(wz)\,}$

is not. Therefore one can state that

${\displaystyle \cos(wz)+i\sin(wz){\text{ is one value of }}\left(\cos z+i\sin z\right)^{w}.\,}$

This formula can be used to find the n^th roots of a complex number. This application does not strictly use de Moivre's formula as the power isn't an integer. However considering the right hand side to the power of n will in each case give the same value left hand side.

If z is a complex number, written in polar form as

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

then

${\displaystyle z^{1/n}=\left[r\left(\cos x+i\sin x\right)\right]^{1/n}=r^{1/n}\left[\cos \left({\frac {x+2k\pi }{n}}\right)+i\sin \left({\frac {x+2k\pi }{n}}\right)\right]}$

where k is an integer. To get the n different roots of z one only needs to consider values of k from 0 to n − 1.

• Root of unity

• Abramowitz, Milton; Stegun, Irene A. (1964), Handbook of Mathematical Functions, New York: Dover Publications, p. 74, ISBN 0486612724 {{citation}}: Unknown parameter |lastauthoramp= ignored (|name-list-style= suggested) (help).

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