I am interested in computing the power spectrum of a system of particles (~100,000) in 3D space with Python. What I have found so far is a group of functions in Numpy (`fft`

,`fftn`

,..) which compute the discrete Fourier transform, of which the square of the absolute value is the power spectrum. My question is a matter of how my data are being represented - and truthfully may be fairly simple to answer.

The data structure I have is an array which has a shape of (*n*,2), *n* being the number of particles I have, and each column representing either the x, y, and z coordinate of the *n* particles. The function I believe I should be using it the `fftn()`

function, which takes the discrete Fourier transform of an *n*-dimensional array - but it says nothing about the format. How should the data be represented as a data structure to be fed into `fftn`

?

Here is what I've tried so far to test the function:

```
import numpy as np
import random
import matplotlib.pyplot as plt
DATA = np.zeros((100,3))
for i in range(len(DATA)):
DATA[i,0] = random.uniform(-1,1)
DATA[i,1] = random.uniform(-1,1)
DATA[i,2] = random.uniform(-1,1)
FFT = np.fft.fftn(DATA)
PS = abs(FFT)**2
plt.plot(PS)
plt.show()
```

The array entitled `DATA`

is a mock array, ultimately the thing which will be 100,000 by 3 in shape. The output of the code gives me something like:

As you can see, I think this is giving me three 1D power spectra (1 for each column of my data), but really I'd like a power spectrum as a function of radius.

Does anybody have any advice or alternative methods/packages they know of to compute the power spectrum (I'd even settle for the two point autocorrelation function).