Using one of the most beautiful formulas of mathematics, Euler's formula

`exp(i*x) = cos(x) + i*sin(x)`

,

substituting `x := n * phi`

:

`cos(n*phi) = Re( exp(i*n*phi) )`

`sin(n*phi) = Im( exp(i*n*phi) )`

`exp(i*n*phi) = exp(i*phi) ^ n`

Power `^n`

is `n`

repeated multiplications.
Therefore you can calculate `cos(n*phi)`

and simultaneously `sin(n*phi)`

by repeated complex multiplication by `exp(i*phi)`

starting with `(1+i*0)`

.

Code examples:

Python:

```
from math import *
DEG2RAD = pi/180.0 # conversion factor degrees --> radians
phi = 10*DEG2RAD # constant e.g. 10 degrees
c = cos(phi)+1j*sin(phi) # = exp(1j*phi)
h=1+0j
for i in range(1,10):
h = h*c
print "%d %8.3f"%(i,h.real)
```

or C:

```
#include <stdio.h>
#include <math.h>
// numer of values to calculate:
#define N 10
// conversion factor degrees --> radians:
#define DEG2RAD (3.14159265/180.0)
// e.g. constant is 10 degrees:
#define PHI (10*DEG2RAD)
typedef struct
{
double re,im;
} complex_t;
int main(int argc, char **argv)
{
complex_t c;
complex_t h[N];
int index;
c.re=cos(PHI);
c.im=sin(PHI);
h[0].re=1.0;
h[0].im=0.0;
for(index=1; index<N; index++)
{
// complex multiplication h[index] = h[index-1] * c;
h[index].re=h[index-1].re*c.re - h[index-1].im*c.im;
h[index].im=h[index-1].re*c.im + h[index-1].im*c.re;
printf("%d: %8.3f\n",index,h[index].re);
}
}
```