Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

I've tried to replicate the main bottleneck in one of my programs.

I want to get the linearly (or rather bilinearly) interpolated values of several non-integer pixel values simultaneously. It is not the case that each pixel coordinate is perturbed in the same way. Below is a complete/minimal script along with comments that demonstrates the problem. How can I speed up the calculation of result?

import numpy as np
import time

im = np.random.rand(640,480,3) # my "image"
xx, yy = np.meshgrid(np.arange(im.shape[1]), np.arange(im.shape[0]))
print "Check these are the right indices:",np.sum(im - im[yy,xx,:])

# perturb the indices slightly
# I want to calculate the interpolated
# values of "im" at these locations
xx = xx + np.random.normal(size=im.shape[:2])
yy = yy + np.random.normal(size=im.shape[:2])

# integer value/pixel locations
x_0 = np.int_(np.modf(xx)[1])
y_0 = np.int_(np.modf(yy)[1])
x_1, y_1 = x_0 + 1, y_0 + 1

# the real-valued offsets/coefficients pixels
a = np.modf(xx)[0][:,:,np.newaxis]
b = np.modf(yy)[0][:,:,np.newaxis]

# make sure we don't go out of bounds at edge pixels

# now perform linear interpolation: THIS IS THE BOTTLENECK!
tic = time.time()
result = ((1-a) * (1-b) * im[y_0, x_0, :] +
             a  * (1-b) * im[y_1, x_0, :] +
          (1-a) *    b  * im[y_0, x_1, :] +
             a  *    b  * im[y_1, x_1, :] )
toc = time.time()

print "interpolation time:",toc-tic
share|improve this question
Any reason why you're avoiding scipy.ndimage.map_coordinates? (E.g. wanting to avoid a dependency on scipy.ndimage?) If not, it's the function you want. – Joe Kington Feb 23 '12 at 16:24
@JoeKington I wasn't aware of this - let me see if I can use this function and if it's faster. Thanks. – YXD Feb 23 '12 at 16:26
up vote 4 down vote accepted

Thanks to @JoeKington for the suggestion. Here's the best I can come up with using scipy.ndimage.map_coordinates

# rest as before
from scipy import ndimage
tic = time.time()
new_result = np.zeros(im.shape)
coords = np.array([yy,xx,np.zeros(im.shape[:2])])
for d in range(im.shape[2]):
    new_result[:,:,d] = ndimage.map_coordinates(im,coords,order=1)
    coords[2] += 1
toc = time.time()
print "interpolation time:",toc-tic

Update: Added the tweaks suggested in the comments and tried one or two other things. This is the fastest version:

tic = time.time()
new_result = np.zeros(im.shape)
coords = np.array([yy,xx])
for d in range(im.shape[2]):
                            output=new_result[:,:,d] )
toc = time.time()

print "interpolation time:",toc-tic

Example running time:

 original version: 0.463063955307
   better version: 0.204537153244
     best version: 0.121845006943
share|improve this answer
Sorry I didn't post an example earlier. I was running short on time. Glad you got it figured out! You can do it with one call to map_coordinates, but depending on the size of your image, iterating through each band is probably a better option. Storing a temporary 3D array of coordinates eats up a lot of ram. You could speed things up a bit if you only pass in one band at a time to map_coordinates. It would also allow you to skip the zeros array in coords. – Joe Kington Feb 23 '12 at 19:16
Also, in the case of bilinear interpolation, you can save a bit of memory and speed things up slightly if you specify prefilter=False. With a small image you won't notice a difference, but with larger images, it avoids making an additional copy in memory. – Joe Kington Feb 23 '12 at 19:20

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.