I'm trying to improve the speed of a function that calculates the normalized cross-correlation between a search image and a template image by using the
anfft module, which provides Python bindings for the FFTW C library and seems to be ~2-3x quicker than
scipy.fftpack for my purposes.
When I take the FFT of my template, I need the result to be padded to the same size as my search image so that I can convolve them. Using
scipy.fftpack.fftn I would just use the
shape parameter to do padding/truncation, but
anfft.fftn is more minimalistic and doesn't do any zero-padding itself.
When I try and do the zero padding myself, I get a very different result to what I get using
shape. This example uses just
scipy.fftpack, but I have the same problem with
import numpy as np from scipy.fftpack import fftn from scipy.misc import lena img = lena() temp = img[240:281,240:281] def procrustes(a,target,padval=0): # Forces an array to a target size by either padding it with a constant or # truncating it b = np.ones(target,a.dtype)*padval aind = [slice(None,None)]*a.ndim bind = [slice(None,None)]*a.ndim for dd in xrange(a.ndim): if a.shape[dd] > target[dd]: diff = (a.shape[dd]-b.shape[dd])/2. aind[dd] = slice(np.floor(diff),a.shape[dd]-np.ceil(diff)) elif a.shape[dd] < target[dd]: diff = (b.shape[dd]-a.shape[dd])/2. bind[dd] = slice(np.floor(diff),b.shape[dd]-np.ceil(diff)) b[bind] = a[aind] return b # using scipy.fftpack.fftn's shape parameter F1 = fftn(temp,shape=img.shape) # doing my own zero-padding temp_padded = procrustes(temp,img.shape) F2 = fftn(temp_padded) # these results are quite different np.allclose(F1,F2)
I suspect I'm probably making a very basic mistake, since I'm not overly familiar with the discrete Fourier transform.