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?