# How does a convolution matrix work?

I know this isn't very relevant to programming, but I need to know how a convolution matrix works for a PHP GD function. I've searched a lot on Google, but can't find anything that explains it well.

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–  Marco Demaio Dec 7 '12 at 12:33

The operation replaces each pixel with the weighted average of the pixels around it, where the weights are given by the matrix. Here's an example convolution matrix:

``````1 1 1
1 1 1
1 1 1
``````

What this does is replace each pixel with the average value of the 3x3 block centered on that pixel. Here's another:

``````0 0 0
0 1 0
0 0 0
``````

This matrix doesn't do anything, it gives you the original back.

The weights can be negative, too. This matrix subtracts the average value of the pixels next to a pixel:

`````` 0 -1  0
-1  4 -1
0 -1  0
``````

Convolution matrices allow you to do fine-tuned blurring and sharpening effects. You can tune the directionality and the frequency response of filters using a convolution matrix, if it's large enough. However, it's usually used for quick-n-dirty blurring and sharpening.

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What is ment by the "value" of the pixel? The x/y coords, or the colour values? –  Hussain Feb 8 '10 at 4:01
Hussain, the value is always the colour representation in some colour space, such as Grayscale, RGB etc. In the latter, each pixel has three "values", one per channel. –  yati sagade Nov 14 '12 at 11:09

I don't know specifically for PHP, but in general a convolution matrix is used to implement certain kinds of image processing effects.

A simple example taken from the PHP manual on GD http://www.php.net/manual/en/function.imageconvolution.php:

Let's say you have a matrix like this:

``````\$M = array(array( 2,  0,  0),
array( 0, -1,  0),
array( 0,  0, -1));
``````

When you apply that convolution matrix to an image, then for each pixel located at (x,y) in the image, the corresponding pixel in the output becomes:

``````\$I = \$in_image;
\$out_image[x,y] = \$I[x-1,y-1]*\$M[0][0] + \$I[x,y-1]*\$M[0][1] + \$I[x+1,y-1]*\$M[0][2]
+ \$I[x-1,y]  *\$M[1][0] + \$I[x,y]  *\$M[1][1] + \$I[x+1,y]  *\$M[1][2]
+ \$I[x-1,y+1]*\$M[2][0] + \$I[x,y+1]*\$M[2][1] + \$I[x+1,y+1]*\$M[2][2];
``````

In other words, the convolution matrix is used to compute each result pixel as a linear combination of the source pixel and the pixels surrounding it.

The divisor parameter is used to divide the whole result by something (this is usually the sum of all the values in the matrix) and the offset is used to add a constant term to the final output value.

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I saw them being used for transport planning once... it freaked me out. –  Slomojo Dec 10 '12 at 2:52