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So, I'm trying to write an algorithm croot(k, n), that returns the kth root of unity with n == n. I'm getting mostly the right answer, however it's giving me really weird representations that seem wrong for certain numbers. Here is an example.

import cmath

def croot(k, n):
    if n<=0:
        return None
    return cmath.exp((2 * cmath.pi * 1j * k) / n)


for k in range(8):
    print croot(k, 8)

Output is:

(1+0j)
(0.70710...+0.70710...j)
(6.12323399574e-17+1j)

Whoa whoa whoa. So the root when k = 2 and n = 8 is wrong, as it should just be i, which would be represented like 1j, or j, or 1.00000j, etc. Could somebody help me here? I'm doing this because I'm trying to write an FFT algorithm. I'm not very experienced with complex numbers and Python so I could very well be making a simple mistake.

Thanks,

If you guys need any additional information just ask.

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1  
Just so you know, you already have this functionality in numpy.. –  wim Mar 15 '13 at 4:04
    
Oh god thank you so much. –  robins35 Mar 15 '13 at 4:04
    
Wait, did you mean functionality for roots of unity, or for fft, because this is for an assignment and I need to write the fft part myself. –  robins35 Mar 15 '13 at 4:11
    
for roots of unity –  wim Nov 7 '13 at 1:41

2 Answers 2

up vote 4 down vote accepted

Look at this number

(6.12303176911e-17+1j)

6.12303176911e-17 = 0.0000000000000000612303176911 which is really small (close to zero). What you are seeing is rounding errors due to the limited representation of floating point numbers

The error is equivalent to measuring the distance to the sun to within 10 microns or so. If you're running FFTs on data from the real world the measurement errors are usually far larger than this.

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What? 6.12303176911e = 16.644 according to my calculator –  robins35 Mar 15 '13 at 4:06
1  
@Scriptonaut: The "e" here means "times ten to the power of", not the base of the natural logarithms. It's ~6.123 * 10^(-17). –  DSM Mar 15 '13 at 4:07
2  
Try typing 1e-3 and 1e-4 into interactive interpreter and you'll get the idea ;) –  wim Mar 15 '13 at 4:11
    
Oh, wow I always saw it like: 1E-3. –  robins35 Mar 15 '13 at 4:12

Here's cube roots of unity and 4th roots for a usage example. The input array should be interpreted as polynomial coefficients.

>>> import numpy as np
>>> np.roots([1, 0, 0, -1])
array([-0.5+0.8660254j, -0.5-0.8660254j,  1.0+0.j       ])
>>> np.roots([1, 0, 0, 0, -1])
array([ -1.00000000e+00+0.j,   5.55111512e-17+1.j,   5.55111512e-17-1.j,
         1.00000000e+00+0.j])

edit: The polynomial coefficients are given in the input array p to np.roots(p) in the following order:

p[0] * x**n + p[1] * x**(n-1) + ... + p[n-1]*x + p[n]

So, for example, to return the nth roots of unity, which are the solutions of the equation 1 * x**n - 1 == 0, you would use an input like p = [1] + [0] * (n - 1) + [-1].

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So, this returns an array of all the roots of unity given a set of polynomial coefficients? Could you explain exactly what's going on here? –  robins35 Mar 15 '13 at 4:11
1  
OK I added some further explatition –  wim Mar 15 '13 at 4:42

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