# scipy.signal.fftconvolve doesn't give the required results

I have a question regarding python's fftconvovle. In my current research I've been required to calculate some convolution between two functions. To do so I'm calculating it using fourier transform (which I used numpy.fft and normalize it) . The thing is that if I want to compare it using fftconvovle package, it fails to give the correct results. Here is my code:

``````#!/usr/bin/python
import numpy as np
from scipy.signal import fftconvolve , convolve

def FFT(array , sign):
if sign==1:
return np.fft.fftshift(np.fft.fft(np.fft.fftshift(array))) * dw / (2.0 * np.pi)
elif sign==-1:
return np.fft.fftshift(np.fft.ifft(np.fft.fftshift(array))) * dt * len(array)

def convolve_arrays(array1,array2,sign):
sign = int(sign)
temp1 = FFT(array1 , sign,)
temp2 = FFT(array2 , sign,)
temp3 = np.multiply(temp1 , temp2)
return  FFT(temp3 , -1 * sign) / (2. * np.pi)

""" EXAMPLE """

dt    = .1
N     = 2**17
t_max = N * dt / 2
time  = dt * np.arange(-N / 2 , N / 2 , 1)

dw    = 2. * np.pi / (N * dt)
w_max = N * dw / 2.
w     = dw * np.arange(-N / 2 , N / 2 , 1)

eta_fourier = 1e-10

Gamma   = 1.
epsilon = .5
omega   = .5

G    = zeros(N , complex)
G[:] = 1. / (w[:] - epsilon + 1j * eta_fourier)

D    = zeros(N , complex)
D[:] = 1. / (w[:] - omega + 1j * eta_fourier) - 1. / (w[:] + omega + 1j * eta_fourier)

H    = convolve_arrays(D , G , 1)
J    = fftconvolve(D , G , mode = 'same') * np.pi  / (2. * N)
``````

If you plot the real/imaginary part of H,J you'll see a shift in the w axes and also I hade to multiple the J's results in order to get some how close (but still not) to the correct results.

Any suggestions?

Thanks!

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Go and take a look at `scipy.fftconvolve` and observe that the algorithm has none of your strange fft shifts or scalings. What are you trying to achieve with the `FFT` function? – Henry Gomersall Oct 8 '13 at 10:06

Boundary conditions are important when you compute convolutions.

When you convolve two signals, the edges of the result depend on what values you assume outside the edges of the inputs. `fftconvolve` computes convolution assuming zero-padded boundaries.

Take a look at the source code of fftconvolve. Notice the shenanigans they go through to achieve zero-padded boundary conditions, in particular, these lines:

``````size = s1 + s2 - 1
``````

...

``````fsize = 2 ** np.ceil(np.log2(size)).astype(int) #For speed; often suboptimal!
fslice = tuple([slice(0, int(sz)) for sz in size])
``````

...

``````ret = ifftn(fftn(in1, fsize) * fftn(in2, fsize))[fslice].copy()
``````

...

``````return _centered(ret, s1) #strips off padding
``````

This is good stuff! It's probably worth reading `fftconvolve`'s code carefully, and a good education if you want to understand Fourier-based convolution.

Brief sketch

The forward FFT zero-pads each signal to prevent periodic boundary conditions:

``````a = np.array([3, 4, 5])
b = np.fft.ifftn(np.fft.fftn(a, (5,))).real
print b #[ 3.  4.  5.  0.  0.]
``````

the inverse FFT of the product of the forward FFTs gives a padded result:

``````a = np.array([3, 4, 5])
b = np.array([0., 0.9, 0.1])
b = np.fft.ifftn(np.fft.fftn(a, (5,))*
np.fft.fftn(b, (5,))
).real
print b #[ 0.   2.7  3.9  4.9  0.5]
``````

and the `_centered` function strips off the extra padding pixels at the end (assuming you use the `mode='same'` option).

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