I am working on a project which requires to find how much a new image has shifted and rotated w.r.t the old image. I am trying to implement it using fft. However, it works for some cases and fails for others. The steps i follow are:

- take the two images, implement canny edge detection
- find out the shift using fft and remove the shift
- transform the image to polar domain and find the shift and convert the answer to radians

In some cases, I get the correct answer but in other cases I get shift as (0,0) and rotation as 0 radians. Please suggest the reason why this may happen.

Here is the code:

```
class Register:
'''
Class for registering images based on FFT. The usage is as follows:
>>> im0 = imread('image0.jpg', flatten = True)
>>> im1 = imread('image1.jpg', flatten = True)
>>> reg = Register(im0, im1)
>>> shift = reg.shift
>>> rotation = reg.theta
Note:
1. This image registration technique is not very reliable and
is valid only for small rotation
2. The class is very slow, since it depends on canny edge detection
module for finding edges.
'''
def __init__(self,imin0, imin1, PROCESSED = False):
'''
This method is used to execute all the routines required to get the
shift and the rotation
'''
# find edges to remove low frequency signals and suppress information
if PROCESSED:
im0 = imin0
im1 = imin1
else:
im0 = Canny(imin0, 0.85, 5).grad
im1 = Canny(imin1, 0.85, 5).grad
# A major drawback of this method is that it can operate only on square
# images. Hence we will make square image of any input image
im0 = self.createsquareim(self.clearBorder(im0))
im1 = self.createsquareim(self.clearBorder(im1))
self.shift = self.findShift(im0,im1)
imtrans = shift(im1, self.shift)
# Remove the shift in the image. This is mandatory before we find theta
impolar0 = self.makePolar(im0)
impolar1 = self.makePolar(imtrans)
self.index = self.findShift(impolar0, impolar1)[1]
self.theta = ((self.index*90.0)/impolar1.shape[0])
def clearBorder(self,im,width = 50, color = 255):
'''
A little house keeping to clear any border noise
'''
im[:,:width] = color
im[:,-width:] = color
im[:width,:] = color
im[-width:,:] = color
return im
def createsquareim(self, im):
"""
function createsquareim
input:numpy ndarray
output:numpy ndarray
The function takes in an image array and converts it into square
image by creating empty columns and rows.
"""
lenmax = max(im.shape[0],im.shape[1])
imout = zeros((lenmax,lenmax))
imout[:,:] = 255
imout[:im.shape[0],:im.shape[1]] = im
return imout
def findShift(self, im0, im1):
'''
This method is based on fft method of registering images.
'''
IM0 = fft2(im0)
IM1 = fft2(im1)
numer = IM0*conj(IM1)
denom = abs(IM0*IM1)
pulse_im = ifft2(numer/denom)
mag = abs(pulse_im)
x, y = where(mag == mag.max())
x = array(x.tolist()) # Issues with read only arrays
y = array(y.tolist())
X, Y = im0.shape
if x > X/2:
x -= X
if y > Y/2:
y -= Y
return [x[0], y[0]]
def makePolar(self, im):
'''
This method will convert the cartesian coordinates image
to polar coordinates image. The relation between the two
domains is
F(r,theta) = f(r*cos(theta),r*sin(theta))
To make the process fast, we are using map_coordinates function
'''
m, n = im.shape
r_max = hypot(m, n)
r_mat = zeros_like(im)
t_mat = zeros_like(im)
r_mat.T[:] = linspace(0, r_max, m)
t_mat[:] = linspace(0, pi/2, n)
x = r_mat*cos(t_mat)
y = r_mat*sin(t_mat)
imout = zeros_like(im)
imout = map_coordinates(im, [x, y], cval = 255)
return imout
```