I have a range image of a scene. I traverse the image and calculate the average change in depth under the detection window. The detection windows changes size based on the average depth of the surrounding pixels of the current location. I accumulate the average change to produce a simple response image.

Most of the time is spent in the for loop, it is taking about 40+s for a 512x52 image on my machine. I was hoping for some speed up. Is there a more efficient/faster way to traverse the image? Is there a better pythonic/numpy/scipy way to visit each pixel? Or shall I go learn cython?

**EDIT:** I have reduced running time to about 18s by using scipy.misc.imread() instead of skimage.io.imread(). Not sure what the difference is, I will try to investigate.

Here is a simplified version of the code:

```
import matplotlib.pylab as plt
import numpy as np
from skimage.io import imread
from skimage.transform import integral_image, integrate
import time
def intersect(a, b):
'''Determine the intersection of two rectangles'''
rect = (0,0,0,0)
r0 = max(a[0],b[0])
c0 = max(a[1],b[1])
r1 = min(a[2],b[2])
c1 = min(a[3],b[3])
# Do we have a valid intersection?
if r1 > r0 and c1 > c0:
rect = (r0,c0,r1,c1)
return rect
# Setup data
depth_src = imread("test.jpg", as_grey=True)
depth_intg = integral_image(depth_src) # integrate to find sum depth in region
depth_pts = integral_image(depth_src > 0) # integrate to find num points which have depth
boundary = (0,0,depth_src.shape[0]-1,depth_src.shape[1]-1) # rectangle to intersect with
# Image to accumulate response
out_img = np.zeros(depth_src.shape)
# Average dimensions of bbox/detection window per unit length of depth
model = (0.602,2.044) # width, height
start_time = time.time()
for (r,c), junk in np.ndenumerate(depth_src):
# Find points around current pixel
r0, c0, r1, c1 = intersect((r-1, c-1, r+1, c+1), boundary)
# Calculate average of depth of points around current pixel
scale = integrate(depth_intg, r0, c0, r1, c1) * 255 / 9.0
# Based on average depth, create the detection window
r0 = r - (model[0] * scale/2)
c0 = c - (model[1] * scale/2)
r1 = r + (model[0] * scale/2)
c1 = c + (model[1] * scale/2)
# Used scale optimised detection window to extract features
r0, c0, r1, c1 = intersect((r0,c0,r1,c1), boundary)
depth_count = integrate(depth_pts,r0,c0,r1,c1)
if depth_count:
depth_sum = integrate(depth_intg,r0,c0,r1,c1)
avg_change = depth_sum / depth_count
# Accumulate response
out_img[r0:r1,c0:c1] += avg_change
print time.time() - start_time, " seconds"
plt.imshow(out_img)
plt.gray()
plt.show()
```