I am trying to perform a 2d convolution in python using numpy

I have a 2d array as follows with kernel H_r for the rows and H_c for the columns

data = np.zeros((nr, nc), dtype=np.float32)

#fill array with some data here then convolve

for r in range(nr):
    data[r,:] = np.convolve(data[r,:], H_r, 'same')

for c in range(nc):
    data[:,c] = np.convolve(data[:,c], H_c, 'same')

data = data.astype(np.uint8);

It does not produce the output that I was expecting, does this code look OK, I think the problem is with the casting from float32 to 8bit. Whats the best way to do this


  • In what way is the output not what you were expecting? – Justin Peel Mar 15 '10 at 15:11
  • Hi, its not the same as what matlab is producing – mikip Mar 15 '10 at 15:18
  • How are you casting this in Matlab? Is it a difference of rounding vs. truncation? – Justin Peel Mar 15 '10 at 22:44

Edit [Jan 2019]

@Tashus comment bellow is correct, and @dudemeister's answer is thus probably more on the mark. The function he suggested is also more efficient, by avoiding a direct 2D convolution and the number of operations that would entail.

Possible Problem

I believe you are doing two 1d convolutions, the first per columns and the second per rows, and replacing the results from the first with the results of the second.

Notice that numpy.convolve with the 'same' argument returns an array of equal shape to the largest one provided, so when you make the first convolution you already populated the entire data array.

One good way to visualize your arrays during these steps is to use Hinton diagrams, so you can check which elements already have a value.

Possible Solution

You can try to add the results of the two convolutions (use data[:,c] += .. instead of data[:,c] = on the second for loop), if your convolution matrix is the result of using the one dimensional H_r and H_c matrices like so:

convolution core addition

Another way to do that would be to use scipy.signal.convolve2d with a 2d convolution array, which is probably what you wanted to do in the first place.

  • 1
    Not "replacing the results from the first with the results of the second", but rather convolving each row with the horizontal kernel, then convolving each column of those results with the vertical kernel. This is a particular mode of conv in MATLAB. – Tashus Jan 4 at 20:09
  • You are right, on the second loop each array element already has the result from the first convolution - the equivalent H2d would have non-null elements on the corners, which is probably better... I just realised this is what is used for blur filters on pictures to avoid the enormous number of operations a direct 2D convolution would require. Then @dudemeister 's answer is probably on the right track. – berna1111 Jan 6 at 2:15

Since you already have your kernel separated you should simply use the sepfir2d function from scipy:

from scipy.signal import sepfir2d
convolved = sepfir2d(data, H_r, H_c)

On the other hand, the code you have there looks all right ...

  • Hi Dudemaster, I think the problem is that I am casting the output to 8bit using this command data = np.array(data,dtype=np.int8) Is this OK – mikip Mar 15 '10 at 15:31
  • @mikip are your numbers in the range of -128 to 127 before you convert them to 8bit? If not, then that is drastically changing your output. – Justin Peel Mar 15 '10 at 16:11
  • Well that really depends on the implementation of the convolve and also your kernel. It might be worth a try to cast both your kernel and data to float or int32 at least. Note that any decent 8bit convolution algorithm should work with (at least) 16bit temporary values because the summing during the convolve can easily overfloat 8bit values, depending on the kernel. – dudemeister Mar 16 '10 at 12:33

Maybe it is not the most optimized solution, but this is an implementation I used before with numpy library for Python:

def convolution2d(image, kernel, bias):
    m, n = kernel.shape
    if (m == n):
        y, x = image.shape
        y = y - m + 1
        x = x - m + 1
        new_image = np.zeros((y,x))
        for i in range(y):
            for j in range(x):
                new_image[i][j] = np.sum(image[i:i+m, j:j+m]*kernel) + bias
return new_image

I hope this code helps other guys with the same doubt.



Try to first round and then cast to uint8:

data = data.round().astype(np.uint8);

This code incorrect:

for r in range(nr):
    data[r,:] = np.convolve(data[r,:], H_r, 'same')

for c in range(nc):
    data[:,c] = np.convolve(data[:,c], H_c, 'same')

See Nussbaumer transformation from multidimentional convolution to one dimentional.

  • 2
    This answer is very vague. What's incorrect about it? What aspect to the Nussbaumer transformation are you referring to? – Hannes Johansson Jul 3 '15 at 8:10

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