I'm trying to resolve the correspondence problem for motion tracking:

Find a given block of dimension m*n, from the frame n-1, in the frame n. I'm using opencv and python (both for the first time ) and I'm calculating the normalized squared difference but it's too slow. I suppose that in some way I can use the discrete Fourier transform, but I'm not able to figure out how I can do it!

```
def match(img, block):
# img is the frame n, block is from frame n-1
w, h = img.shape[:2]
output = np.zeros( (w,h) ) + 255
for x in range( w ):
for y in range( h ):
output[x, y] = evaluate(img, (x,y) , block)
# the minimum value is the position of the block into the frame n
return output
def evaluate( img, point, block):
m, n = block.shape[:2]
w, h = img.shape[:2]
a = (m-1)/2
b = (n-1)/2
x, y = point
response = 0
for s in range( -a, a+1 ):
for t in range(-b, b+1 ):
if x+s >= w or x+s < 0 or y+t >= h or y+t < 0:
pixel = 0
else:
pixel = img[x+s, y+t]
# normalized squared difference
response = response + (pow((block[ 1+s, 1+t] - pixel), 2) / (m*n))
return response
```

`m x n`

is a template, so why did you skip the obvious normalized cross-correlation ? It is implemented in OpenCV, so you don't have to do anything basically. – mmgp Jan 23 '13 at 1:18