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The scipy.fftpack.rfft function returns the DFT as a vector of floats, alternating between the real and complex part. This means to multiply to DFTs together (for convolution) I will have to do the complex multiplication "manually" which seems quite tricky. This must be something people do often - I presume/hope there is a simple trick to do this efficiently that I haven't spotted?

Basically I want to fix this code so that both methods give the same answer:

import numpy as np
import scipy.fftpack as sfft

X = np.random.normal(size = 2000)
Y = np.random.normal(size = 2000)
NZ = np.fft.irfft(np.fft.rfft(Y) * np.fft.rfft(X))
SZ = sfft.irfft(sfft.rfft(Y) * sfft.rfft(X))    # This multiplication is wrong

array([-43.23961083,  53.62608086,  17.92013729, ..., -16.57605207,
     8.19605764,   5.23929023])
array([-19.90115323,  16.98680347,  -8.16608202, ..., -47.01643274,
    -3.50572376,  58.1961597 ])

N.B. I am aware that fftpack contains a convolve function, but I only need to fft one half of the transform - my filter can be fft'd once in advance and then used over and over again.

share|improve this question
up vote 1 down vote accepted

You can take a view of a slice of your return array, e.g.:

>>> scipy.fftpack.fft(np.arange(8))
array([ 28.+0.j        ,  -4.+9.65685425j,  -4.+4.j        ,
        -4.+1.65685425j,  -4.+0.j        ,  -4.-1.65685425j,
        -4.-4.j        ,  -4.-9.65685425j])
>>> a = scipy.fftpack.rfft(np.arange(8))
>>> a
array([ 28.        ,  -4.        ,   9.65685425,  -4.        ,
         4.        ,  -4.        ,   1.65685425,  -4.        ])
>>> a.dtype
>>> a[1:-1].view(np.complex128) # First and last entries are real
array([-4.+9.65685425j, -4.+4.j        , -4.+1.65685425j])

You will need to handle even or odd sized FFTs differently:

>>> scipy.fftpack.fft(np.arange(7))
array([ 21.0+0.j        ,  -3.5+7.26782489j,  -3.5+2.79115686j,
        -3.5+0.79885216j,  -3.5-0.79885216j,  -3.5-2.79115686j,
>>> a = scipy.fftpack.rfft(np.arange(7))
>>> a
array([ 21.        ,  -3.5       ,   7.26782489,  -3.5       ,
         2.79115686,  -3.5       ,   0.79885216])
>>> a.dtype
>>> a[1:].view(np.complex128)
array([-3.5+7.26782489j, -3.5+2.79115686j, -3.5+0.79885216j])
share|improve this answer
Thanks - never new I could switch into complex so easily! I then of course have to flip back to np.float64 and hstack the first and last pieces back on before passing it back to irfft. Rather annoying that eats up a lot of the speed gain from scipy! Probably not a coincidence... – Corone Aug 31 '13 at 11:00

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