# Representation of complex numbers in C++ for Discrete Fourier Transformation

I am currently writing a small tool which should help me check whether my manually calculated fourier vectors are correct. Now i need the n-th Root of Unity specified by `omega = exp(2*pi*i / n)`. Can somebody explain me how to represent this `omega` as a `complex` in C++?

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Use Euler's formula:

``````exp(2πi/n) = cos(2π/n) + i sin(2π/n)
``````

Then it's easy:

``````complex<double> rootOfUnity(cos(TWOPI/n), sin(TWOPI/n));
``````

(replace TWOPI with either a macro available on your system or just the value of 2π however you see fit).

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Any specific suggestion how to compute pi? Would `4*atan(1.0)` suffice? –  Christian Ivicevic Sep 15 '11 at 21:24
You can either hard-code it, or just use `M_PI`. –  Mysticial Sep 15 '11 at 21:25
Using Visual Studio 2010 on Windows 8 with Microsofts C++ Compiler. Including `cmath.h` does not provide `M_PI`! –  Christian Ivicevic Sep 15 '11 at 21:26
@Christian: yes, using 4.0*atan(1.0) will work fine. Or you can just use `double TWOPI = 6.283185307179586476925286766559`. –  Stephen Canon Sep 15 '11 at 21:29
@Christian: I didn't realize that! :) Because I always define my own Pi macro hard-coded to 50 some digits... lol –  Mysticial Sep 15 '11 at 21:31

Well, the real and imaginary parts of the twiddle factor omega is just:

``````double angle = 2*pi/n;

double real = cos(angle);
double imaj = sin(angle);

complex<double> omega(real, imaj);
``````
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There is a function that returns a complex number using polar coordinates:

``````#include<complex>
complex polar(const T& rho)
complex polar(const T& rho, const T& theta)
``````

where `rho` is the magnitude, and `theta` is the angle in radians.

In this case, `rho` is always 1.0.

``````const double pi = 3.141592653589793238462643383279;
double omega = polar(1.0, 2*pi*i/n);
``````
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