I'm passing some simple IDL code to Python. However the returned FFT values form the SciPy/NumPy packages is different than the IDL one and I can't find out why.

Reducing it all to a simple example of 8 elements I found that the SciPy/NumPy routines return values that are 8 (2^3) times bigger than the IDL ones (a normalization problem I thought).

Here is the example code (copied from here) in both languages:

## IDL

```
signal = ([-2., 8., -6., 4., 1., 0., 3., 5.])
fourier = fft(signal)
print, fourier
```

returns

( 1.62500, 0.00000) ( 0.420495, 0.506282) ( 0.250000, 0.125000) ( -1.17050, -1.74372) ( -2.62500, -0.00000) ( -1.17050, 1.74372) ( 0.250000, -0.125000) ( 0.420495, -0.506282)

## Python

```
from scipy.fftpack import fft
import numpy as N
…
signal = N.array([-2., 8., -6., 4., 1., 0., 3., 5.])
fourier = fft(signal)
print fourier
```

returns

[ 13. +0.j , 3.36396103 +4.05025253j, 2. +1.j , -9.36396103-13.94974747j, -21. +0.j , -9.36396103+13.94974747j, 2. -1.j , 3.36396103 -4.05025253j]

I did it with the NumPy package and I got the same results. I tried also `print fft(signal, 8 )`

just in case but it returned the same, as expected.

However that's not all, coming back to my real array of 256 elements I found that the difference was no longer 8 or 256, but 256*8! it's just insane.

Although I worked around the problem I NEED to know why there is that difference.

**Solved:** It was just the normalization, at some point I divided the IDL 256 array by a factor of 8 that I forgot to remove. In Dougal's answer there is the documentation that I missed.