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I am trying to write up a pixel interpolation(binning?) algorithm (I want to, for example, take four pixels and take their average and produce that average as a new pixel). I've had success with stride tricks to speed up the "partitioning" process, but the actual calculation is really slow. For a 256x512 16-bit grayscale image I get the averaging code to take 7s on my machine. I have to process from 2k to 20k images depending on the data set. The purpose is to make the image less noisy (I am aware my proposed method decreases resolution, but this might not be a bad thing for my purposes).

import numpy as np
from numpy.lib.stride_tricks import as_strided
from scipy.misc import imread
import matplotlib.pyplot as pl
import time

def sliding_window(arr, footprint):
    """ Construct a sliding window view of the array"""
    t0 = time.time()
    arr = np.asarray(arr)
    footprint = int(footprint)
    if arr.ndim != 2:
        raise ValueError("need 2-D input")
    if not (footprint > 0):
        raise ValueError("need a positive window size")
    shape = (arr.shape[0] - footprint + 1,
             arr.shape[1] - footprint + 1, footprint, footprint)
    if shape[0] <= 0:
        shape = (1, shape[1], arr.shape[0], shape[3])
    if shape[1] <= 0:
        shape = (shape[0], 1, shape[2], arr.shape[1])
    strides = (arr.shape[1]*arr.itemsize, arr.itemsize,
               arr.shape[1]*arr.itemsize, arr.itemsize)

    t1 = time.time()
    total = t1-t0
    print "strides"
    print total

    return as_strided(arr, shape=shape, strides=strides)

def binning(w,footprint):

    #the averaging block
    #prelocate memory
    binned = np.zeros(w.shape[0]*w.shape[1]).reshape(w.shape[0],w.shape[1])
    #print w
    t2 = time.time()
    for i in xrange(w.shape[0]):
        for j in xrange(w.shape[1]):
            binned[i,j] = w[i,j].sum()/(footprint*footprint + 0.0)

    t3 = time.time()
    tot = t3-t2
    print tot

    return binned


Is there some built-in/optimized function that would to the same thing I want, or should I just try and make a C extension (or even something else) ?

Below is the additional part of the code just for completeness, since I think the functions are the most important here. Image plotting is slow, but I think there is a way to improve it for example here

for i in range(2000):
    arr = imread("./png/frame_" + str("%05d" % (i + 1) ) + ".png").astype(np.float64)
    w = sliding_window(arr,footprint)
    binned = binning(w,footprint)
    pl.imshow(binned,interpolation = "nearest")
    pl.savefig("binned_" + str(i) + ".png")
    enter code here

What I am looking for could be called interpolation. I just used the term the person who advised me to do this used. Probably that is the reason why I was finding histogram related stuff !

Apart from the median_filter I tried generic_filter from scipy.ndimage but those did not give me the results I wanted (they had no "valid" mode like in convolution i.e. these relied on going out of bounds of the array when moving the kernel arround). I asked in code review and it seems that stackoverflow would be a more suitable place for this question.

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It sounds like you have solved the question, and you should probably use a scipy function. But if you want to speed up your own code you should use numpy's sum. It once gave me a x16 speedup compared to the built-in sum. –  Daniel Thaagaard Andreasen Jul 30 '13 at 18:29

4 Answers 4

Without diving into your code, I think what you what is just to resize the image with interpolation. You should use an image library for this operation, as it will have heavily optimized code.

Since you are using SciPy, you might want to start with PIL, the Python Imaging Library. Use the resize method, were you can pass the desired interpolation parameter, probably Image.BILINEAR in your case.

It should look something like this:

import Image
im = Image.fromarray(your_numpy)
im.resize((w/2, h/2), Image.BILINEAR)

Edit: I just noticed, you can do it even with scipy itself, look at the documentation for


a = np.array([[0,1,2],[3,4,5],[6,7,8],[9,10,11]], dtype=np.uint8)
res = scipy.misc.imresize(a, (3,2), interp="bilinear")
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It does not seem to do what I want... –  Vitto Jul 30 '13 at 16:19
Can you describe how it differs from what you want to do? –  w.m Jul 30 '13 at 16:21
Take for example an array: a = np.array([[0,1,2],[3,4,5],[6,7,8],[9,10,11]]) What I have written returns [[2,3.],[5.,6.],[8.,9.]] i.e. what I want (I know that this as a filter is not a good one, and median is better, but I want to test this one for my purposes), now if I try what you have proposed, I get [[0,23],[58,81],[150,173]]... –  Vitto Jul 30 '13 at 16:44
I've updated the answer. You need to specify the data type, otherwise scipy/PIL will guess, and it guessed your image had a range of [0..15], but gave you the output for 0..255. –  w.m Jul 30 '13 at 17:24
It also seems that imresize does not work with 16-bit images. It gives back 8-bit. And, I am guessing (since the docs are not very clear, at least to me) that it probably attempts to guess how far away these values are from the full range (i.e. 0 - 255) and does something similar to normalization(or contrast stretching), so it guesses how the values would appear ? (This is jibberish, but maybe you will understand what I am trying to say). Anyway, I did not the the result I wanted. –  Vitto Jul 30 '13 at 19:02

You are attempting to do a basic blur mask, effectively. You are creating a new image where each pixel represents a scaled sum of its former neighbors. This would be easiest with a simple 3x3 averaging/smoothing filter, like so:

A = | 1 | 1 | 1 |
    | 1 | 1 | 1 |
    | 1 | 1 | 1 |

There is a length explanation of how to do this, along with documented MATLAB code (which you could reduce to pseudo-code easily enough) in the references below.

You aren't changing the resolution of the images (they only decrease by (n-1)/2, where n is the size of the n x n filter matrix), and there are ways to get around this. You ARE decreasing the sharpness of the image though. You might consider a mode, median, or some type of adaptive filter rather than just straight-up blurring, if it's an option.


  1. Spatial Convolution Masks http://www.giassa.net/?page_id=584
  2. Adaptive Filtering http://www.giassa.net/?page_id=639

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For the average look at scipy.ndimage.filters.uniform_filter, in scipy.ndimage.filters, you have lots kernels for convolution that are much faster than a direct convolution with scipy.convolve.

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OK, it's official - I am an idiot, the solution was stuff I used a couple of weeks ago.

All I needed was a simple scipy.signal.convolve function, with the 2x2 kernel, mode = "valid" and the result divided by 4...(Or fft convolve for speed, but there could be problems with zero padding, not sure yet).

And from whay I have read - median filter should always win, but it is something particular I want to test.

Thanks for your help guys!


I will still leave this as a solution, but in reality I had to do it differently. I really had to decrease the resolution and use stride tricks differently (that is use non overlapping windows ) to make 4 px into 1px and so decreasing the resolution a lot !

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