# De Moivre's formula

In mathematics, **de Moivre's formula ** (a.k.a. **De Moivre's theorem** and **De Moivre's identity**), 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

where *i* is the imaginary unit (*i*^{2} = −1). While the formula was named after de Moivre, he never stated it in his works.^{[1]}

The formula is important because it connects complex numbers 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 *n*th roots of unity, that is, complex numbers *z* such that *z ^{n}* = 1.

## Derivation from Euler's formula

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

and the exponential law for integer powers

Then, by Euler's formula,

A more elementary motivation of the theorem comes from calculating

where the final equality follows from the trigonometric identities

This proves the theorem for the case *n* = 2. Larger values of *n* correspond to trigonometric identities for the triple angle, quadruple angle, etc.

## Proof by induction (for integer *n*)

The truth of de Moivre's theorem can be established by mathematical induction for natural numbers, and extended to all integers from there. For an integer *n*, call the following statement *S*(*n*):

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

Now, considering *S*(*k*+1):

See angle sum and difference identities.

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 (0*x*) + *i* sin(0*x*) = 1 +*i* 0 = 1. Finally, for the negative integer cases, we consider an exponent of -*n* for natural *n*.

The equation (*) is a result of the identity , for *z* = cos *nx* + *i* sin *nx*. Hence, *S*(*n*) holds for all integers *n*.

## Formulas for cosine and sine individually

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Being 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 *x*, and therefore also cos *x* and sin *x*, are real numbers, then the identity of these parts can be written using binomial coefficients. This formula was given by 16th century French mathematician Franciscus Vieta:

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 even valid for complex values of *x*, because both sides are entire (that is, holomorphic on the whole complex plane) functions of *x*, and two such functions that coincide on the real axis necessarily coincide everywhere. Here are the concrete instances of these equations for *n* = 2 and *n* = 3:

**Failed to parse (unknown function "\begin{alignat}"): {\begin{alignedat}2\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{alignedat}}**

The right hand side of the formula for cos(*nx*) is in fact the value *T*_{n}(cos *x*) of the Chebyshev polynomial *T*_{n} at cos *x*.

## Failure for non-integer powers, and generalization

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 *n*. If a complex number is raised to a non-integer power, the result is multiple-valued (see failure of power and logarithm identities). For example, when *n* = ½, de Moivre's formula gives the following results:

- for
*x*= 0 the formula gives 1^{½}= 1, and - for
*x*= 2π the formula gives 1^{½}= −1.

This assigns two different values for the same expression 1^{½}, so the formula is not consistent in this case.

On the other hand, the values 1 and −1 are both square roots of 1. More generally, if *z* and *w* are complex numbers, then

is multi-valued while

is not. However, it is always the case that

is one value of

### Roots of complex numbers

A modest extension of the version of de Moivre's formula given in this article can be used to find the *n*^{th} roots of a complex number (equivalently, the (1/*n*)^{th} power).

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

then the *n* *n*^{th} roots of *z* are given by

where *k* varies over the integer values from 0 to *n* − 1.

This formula is also sometimes known as de Moivre's formula.^{[2]}

## Analogues in other settings

### Hyperbolic trigonometry

Since , an analog to de Moivre's formula also applies to the hyperbolic trigonometry. For all , . Also, if , then one value of will be .^{[3]}

### Quaternions

To find the roots of a quaternion there is an analogous form of de Moivre's formula. A quaternion in the form can be represented in the form for . In this representation, , and the trigonometric functions are defined as and . In the case that , (the unit vector). This leads to the variation of De Moivre's formula:

#### Example

To find the cubic roots of , write the quaternion in the form

Then the cubic roots are given by :

## References

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## External links

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