I'm writing some code to recover the rotation, scaling and translation of a test image relative to a template using phase correlation, a la Reddy & Chatterji 1996. I take the FFT of my original test image in order to find the scale factor and angle of rotation, but I then need the FFT of the rotated and scaled test image in order to get the translation.
Now I could apply rotation and scaling in the spatial domain then take the FFT, but that seems a bit inefficient - is it possible to obtain the Fourier coefficients of the rotated/scaled image directly in the frequency domain?
Edit 1: OK, I had a play around following user1816548's suggestion. I can get vaguely sensible-looking rotations for angles that are multiples of 90o, albeit with odd changes in the polarity of the image. Angles that aren't multiples of 90o give me pretty zany results.
Edit 2: I've applied zero padding to the image, and I'm wrapping the edges of the FFT when I rotate it. I'm quite certain that I'm rotating about the DC component of the FFT, but I still get weird results for angles that aren't multiples of 90o.
Executable Numpy/Scipy code:
import numpy as np from scipy.misc import lena from scipy.ndimage.interpolation import rotate,zoom from scipy.fftpack import fft2,ifft2,fftshift,ifftshift from matplotlib.pyplot import subplots,cm def testFourierRotation(angle): M = lena() newshape = [2*dim for dim in M.shape] M = procrustes(M,newshape) # rotate, then take the FFT rM = rotate(M,angle,reshape=False) FrM = fftshift(fft2(rM)) # take the FFT, then rotate FM = fftshift(fft2(M)) rFM = rotatecomplex(FM,angle,reshape=False) IrFM = ifft2(ifftshift(rFM)) fig,[[ax1,ax2,ax3],[ax4,ax5,ax6]] = subplots(2,3) ax1.imshow(M,interpolation='nearest',cmap=cm.gray) ax1.set_title('Original') ax2.imshow(rM,interpolation='nearest',cmap=cm.gray) ax2.set_title('Rotated in spatial domain') ax3.imshow(abs(IrFM),interpolation='nearest',cmap=cm.gray) ax3.set_title('Rotated in Fourier domain') ax4.imshow(np.log(abs(FM)),interpolation='nearest',cmap=cm.gray) ax4.set_title('FFT') ax5.imshow(np.log(abs(FrM)),interpolation='nearest',cmap=cm.gray) ax5.set_title('FFT of spatially rotated image') ax6.imshow(np.log(abs(rFM)),interpolation='nearest',cmap=cm.gray) ax6.set_title('Rotated FFT') fig.tight_layout() pass def rotatecomplex(a,angle,reshape=True): r = rotate(a.real,angle,reshape=reshape,mode='wrap') i = rotate(a.imag,angle,reshape=reshape,mode='wrap') return r+1j*i def procrustes(a,target,padval=0): 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]-target[dd])/2. aind[dd] = slice(np.floor(diff),a.shape[dd]-np.ceil(diff)) elif a.shape[dd] < target[dd]: diff = (target[dd]-a.shape[dd])/2. bind[dd] = slice(np.floor(diff),target[dd]-np.ceil(diff)) b[bind] = a[aind] return b