I am studying image-processing using NumPy and facing a problem with filtering with convolution.

I would like to convolve a gray-scale image. (convolve a 2d Array with a smaller 2d Array)

Does anyone have an idea to refine my method?

I know that SciPy supports convolve2d but I want to make a convolve2d only by using NumPy.

What I have done

First, I made a 2d array the submatrices.

a = np.arange(25).reshape(5,5) # original matrix

submatrices = np.array([
     [a[:-2,:-2], a[:-2,1:-1], a[:-2,2:]],
     [a[1:-1,:-2], a[1:-1,1:-1], a[1:-1,2:]],
     [a[2:,:-2], a[2:,1:-1], a[2:,2:]]])

the submatrices seems complicated but what I am doing is shown in the following drawing.


Next, I multiplied each submatrices with a filter.

conv_filter = np.array([[0,-1,0],[-1,4,-1],[0,-1,0]])
multiplied_subs = np.einsum('ij,ijkl->ijkl',conv_filter,submatrices)


and summed them.

np.sum(np.sum(multiplied_subs, axis = -3), axis = -3)
#array([[ 6,  7,  8],
#       [11, 12, 13],
#       [16, 17, 18]])

Thus this procedure can be called my convolve2d.

def my_convolve2d(a, conv_filter):
    submatrices = np.array([
         [a[:-2,:-2], a[:-2,1:-1], a[:-2,2:]],
         [a[1:-1,:-2], a[1:-1,1:-1], a[1:-1,2:]],
         [a[2:,:-2], a[2:,1:-1], a[2:,2:]]])
    multiplied_subs = np.einsum('ij,ijkl->ijkl',conv_filter,submatrices)
    return np.sum(np.sum(multiplied_subs, axis = -3), axis = -3)

However, I find this my_convolve2d troublesome for 3 reasons.

  1. Generation of the submatrices is too awkward that is difficult to read and can only be used when the filter is 3*3
  2. The size of the variant submatrices seems to be too big, since it is approximately 9 folds bigger than the original matrix.
  3. The summing seems a little non intuitive. Simply said, ugly.

Thank you for reading this far.

Kind of update. I wrote a conv3d for myself. I will leave this as a public domain.

def convolve3d(img, kernel):
    # calc the size of the array of submatrices
    sub_shape = tuple(np.subtract(img.shape, kernel.shape) + 1)

    # alias for the function
    strd = np.lib.stride_tricks.as_strided

    # make an array of submatrices
    submatrices = strd(img,kernel.shape + sub_shape,img.strides * 2)

    # sum the submatrices and kernel
    convolved_matrix = np.einsum('hij,hijklm->klm', kernel, submatrices)

    return convolved_matrix
  • 2
    thank you for providing drawings of the matrices :) If I understand correctly, you want tips on how to make your solution more elegant? Commented Mar 29, 2017 at 7:24
  • Glad it helps! Yes. I would be grateful if you can provide me tips to overcome the 3 problems written in the very last lines.
    – Allosteric
    Commented Mar 29, 2017 at 7:26
  • I should add that the 3 points are rather arranged in a priority order. The first one is quite important for me and the last one seems kinda trivial. I will also be glad if there are other problems and refinements about it.
    – Allosteric
    Commented Mar 29, 2017 at 7:28
  • 2
    Isn't the second drawing (after the equality sign) wrong? Shouldn't each submatrix be multiplied (element-wise) with the filter, and then the elements of each of the resulting submatrices summed?
    – Andreas K.
    Commented Nov 9, 2018 at 13:34
  • 1
    @AndyK They will produce the same result.
    – Allosteric
    Commented Nov 10, 2018 at 11:38

4 Answers 4


You could generate the subarrays using as_strided:

import numpy as np

a = np.array([[ 0,  1,  2,  3,  4],
       [ 5,  6,  7,  8,  9],
       [10, 11, 12, 13, 14],
       [15, 16, 17, 18, 19],
       [20, 21, 22, 23, 24]])

sub_shape = (3,3)
view_shape = tuple(np.subtract(a.shape, sub_shape) + 1) + sub_shape
strides = a.strides + a.strides

sub_matrices = np.lib.stride_tricks.as_strided(a,view_shape,strides)

To get rid of your second "ugly" sum, alter your einsum so that the output array only has j and k. This implies your second summation.

conv_filter = np.array([[0,-1,0],[-1,5,-1],[0,-1,0]])
m = np.einsum('ij,ijkl->kl',conv_filter,sub_matrices)

# [[ 6  7  8]
#  [11 12 13]
#  [16 17 18]]
  • if a_s is the strided array and filter is your laplacian like filter, then try... np.sum(a_s*filter, axis=(2,3)) if indeed your answer is array([[ 6, 7, 8], [11, 12, 13], [16, 17, 18]])
    – NaN
    Commented Mar 29, 2017 at 8:03
  • Thank you for the tip. I am trying this myself right now. Maybe trivial but I believe that the name filter is not appropriate because it is a built-in function of python.
    – Allosteric
    Commented Mar 29, 2017 at 8:14
  • 1
    You can do the summation directly in the Einstein summation. See answer
    – Crispin
    Commented Mar 29, 2017 at 8:16
  • In this question, isn't it better to write, sub_shape = conv_filter.shape ?
    – Allosteric
    Commented Mar 29, 2017 at 8:22
  • 1
    Is using einsum("ij,klij", ...) sufficient/better? Using the code from this answer with input of different shape, I got operands could not be broadcast together with remapped shapes, using "ij,klij" seems to work without issues. Commented Dec 20, 2021 at 21:16

Cleaned up using as_strided and @Crispin 's einsum trick from above. Enforces the filter size into the expanded shape. Should even allow non-square inputs if the indices are compatible.

def conv2d(a, f):
    s = f.shape + tuple(np.subtract(a.shape, f.shape) + 1)
    strd = numpy.lib.stride_tricks.as_strided
    subM = strd(a, shape = s, strides = a.strides * 2)
    return np.einsum('ij,ijkl->kl', f, subM)
  • simplify further... see my comment below... np.sum(a_s * filter, axis=(2,3)) if indeed your answer is array([[ 6, 7, 8], [11, 12, 13], [16, 17, 18]]) ... where a_s is strided array and filter is the 3x3 filter
    – NaN
    Commented Mar 29, 2017 at 8:07
  • Not sure why that works @NaN since it is certainly not doing what the problem asked - but it does, even for arbitrary a matrices
    – Daniel F
    Commented Mar 29, 2017 at 8:14
  • at least at numpy v12, a.shape and f.shape is a tuple so s should be tuple(np.subtract(a.shape, f.shape)+1), I think.
    – Allosteric
    Commented Mar 29, 2017 at 9:06
  • True! Still used to shape giving an ndarray. Fixed that.
    – Daniel F
    Commented Mar 29, 2017 at 9:09
  • Hi @DanielF, is there a generalization of this that works for RGB? Not super familiar with einsum notation, so an idea how to generalize would be awesome.
    – sirgogo
    Commented May 6, 2018 at 6:14

You can also use fft (one of the faster methods to perform convolutions)

from numpy.fft import fft2, ifft2
import numpy as np

def fft_convolve2d(x,y):
    """ 2D convolution, using FFT"""
    fr = fft2(x)
    fr2 = fft2(np.flipud(np.fliplr(y)))
    m,n = fr.shape
    cc = np.real(ifft2(fr*fr2))
    cc = np.roll(cc, -m/2+1,axis=0)
    cc = np.roll(cc, -n/2+1,axis=1)
    return cc

cheers, Dan

  • It is certainly not efficient to use the FFT for convolution if the kernel has only 9 elements. This is only useful for large kernels. Commented Feb 25, 2020 at 1:43
  • True. It depends on the kernel and image size but the threshold for fft to outperform is very low. It also depends on your computer architecture but for most generic use-cases fft is the go to in high performance libraries.
    – Dan Erez
    Commented Feb 26, 2020 at 17:25
  • 1
    The following article compares the performance of various image convolution methods, and thus, we can conclude that the FFT method of Numpy is the fastest method to perform convolution. laurentperrinet.github.io/sciblog/posts/… Commented Jan 30, 2021 at 20:24
  • Regarding the padding: Would simply adding s=x.shape to fr2 do the trick? As in fr2 = fft2(np.flipud(np.fliplr(y)), s=x.shape) # Pad the filter
    – Stefnotch
    Commented Oct 27, 2023 at 8:51


Check out all the convolution methods and their respective performances here. Also, I found the below code snippet to be simpler.

from numpy.fft  import fft2, ifft2
def np_fftconvolve(A, B):
    return np.real(ifft2(fft2(A)*fft2(B, s=A.shape)))

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