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# Is there a equivalent of scipy.signal.deconvolve for 2D arrays?

I would like to deconvolve a 2D image with a point spread function (PSF). I've seen there is a `scipy.signal.deconvolve` function that works for one-dimensional arrays, and `scipy.signal.fftconvolve` to convolve multi-dimensional arrays. Is there a specific function in scipy to deconvolve 2D arrays?

I have defined a fftdeconvolve function replacing the product in fftconvolve by a divistion:

``````def fftdeconvolve(in1, in2, mode="full"):
"""Deconvolve two N-dimensional arrays using FFT. See convolve.

"""
s1 = np.array(in1.shape)
s2 = np.array(in2.shape)
complex_result = (np.issubdtype(in1.dtype, np.complex) or
np.issubdtype(in2.dtype, np.complex))
size = s1+s2-1

# Always use 2**n-sized FFT
fsize = 2**np.ceil(np.log2(size))
IN1 = fftpack.fftn(in1,fsize)
IN1 /= fftpack.fftn(in2,fsize)
fslice = tuple([slice(0, int(sz)) for sz in size])
ret = fftpack.ifftn(IN1)[fslice].copy()
del IN1
if not complex_result:
ret = ret.real
if mode == "full":
return ret
elif mode == "same":
if np.product(s1,axis=0) > np.product(s2,axis=0):
osize = s1
else:
osize = s2
return _centered(ret,osize)
elif mode == "valid":
return _centered(ret,abs(s2-s1)+1)
``````

However, the code below does not recover the original signal after convolving and deconvolving:

``````sx, sy = 100, 100
X, Y = np.ogrid[0:sx, 0:sy]
star = stats.norm.pdf(np.sqrt((X - sx/2)**2 + (Y - sy/2)**2), 0, 4)
psf = stats.norm.pdf(np.sqrt((X - sx/2)**2 + (Y - sy/2)**2), 0, 10)

star_conv = fftconvolve(star, psf, mode="same")
star_deconv = fftdeconvolve(star_conv, psf, mode="same")

f, axes = plt.subplots(2,2)
axes[0,0].imshow(star)
axes[0,1].imshow(psf)
axes[1,0].imshow(star_conv)
axes[1,1].imshow(star_deconv)
plt.show()
``````

The resulting 2D arrays are shown in the lower row in the figure below. How could I recover the original signal using FFT deconvolution?

-

These functions using fftn, ifftn, fftshift and ifftshift from the SciPy's fftpack package seem to work:

``````from scipy import fftpack

def convolve(star, psf):
star_fft = fftpack.fftshift(fftpack.fftn(star))
psf_fft = fftpack.fftshift(fftpack.fftn(psf))
return fftpack.fftshift(fftpack.ifftn(fftpack.ifftshift(star_fft*psf_fft)))

def deconvolve(star, psf):
star_fft = fftpack.fftshift(fftpack.fftn(star))
psf_fft = fftpack.fftshift(fftpack.fftn(psf))
return fftpack.fftshift(fftpack.ifftn(fftpack.ifftshift(star_fft/psf_fft)))

star_conv = convolve(star, psf)
star_deconv = deconvolve(star_conv, psf)

f, axes = plt.subplots(2,2)
axes[0,0].imshow(star)
axes[0,1].imshow(psf)
axes[1,0].imshow(np.real(star_conv))
axes[1,1].imshow(np.real(star_deconv))
plt.show()
``````

The image in the left bottom shows the convolution of the two Gaussian functions in the upper row, and the reverse of the effects of convolution is shown in the bottom right.

-

Note that deconvolving by division in the fourier domain isn't really useful for anything but demonstration purposes; any kind of noise, even numerical, may render your outcome completely unusable. One may regularize the noise in various ways; but in my experience, an RL iteration is easier to implement, and in many ways more physically justifiable.

-
What about division in f domain with a waterlevel, `spec_out = spec_signal / (spec_to_deconv+waterlevel)` rather than `spec_out = spec_signal / spec_to_deconv`? Avoid small perturbations of small values in `spec_to_deconv` resulting in large variations in `spec_out`. – Lee Jul 18 at 10:31
That's essentially the idea behind a Wiener filter; but it has at best strenuous physical justification, and setting the threshold will always involve a compromise between the noise suppression and the distortion which is introduced. – Eelco Hoogendoorn Jul 18 at 10:40
Is the RL iteration applicable to 1d time series too? – Lee Jul 18 at 15:34
Its applicable to any linear inversion problem where both the right-hand side, the solution, and the operator have strictly non-negative coefficients. – Eelco Hoogendoorn Jul 18 at 18:02