# Implementing Gaussian Blur - How to calculate convolution matrix (kernel)

My question is very close to this question: How do I gaussian blur an image without using any in-built gaussian functions?

The answer to this question is very good, but it doesn't give an example of actually calculating a real Gaussian filter kernel. The answer gives an arbitrary kernel and shows how to apply the filter using that kernel but not how to calculate a real kernel itself. I am trying to implement a Gaussian blur in C++ or Matlab from scratch, so I need to know how to calculate the kernel from scratch.

I'd appreciate it if someone could calculate a real Gaussian filter kernel using any small example image matrix.

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Have you read this: en.wikipedia.org/wiki/Gaussian_function? –  Oli Charlesworth Nov 20 '11 at 21:01
Or even this: en.wikipedia.org/wiki/Gaussian_blur –  Bart Nov 20 '11 at 21:10
Yes, I've spent a lot of time trying to understand those. What I need is a step by step example. After I understand it, I'll probably add the example to the Gaussian Blur page. –  gsingh2011 Nov 20 '11 at 21:24
@gsingh2011: This is a nice thought, but probably pointless. Gaussian kernels are not created explicitly normally because they are separable if the correlation is 0. –  thiton Nov 20 '11 at 21:33

You can create a Gaussian kernel from scratch as noted in MATLAB documentation of `fspecial`. Please read the Gaussian kernel creation formula in the algorithms part in that page and follow the code below. The code is to create an m-by-n matrix with sigma = 1.

``````m = 5; n = 5;
sigma = 1;
[h1, h2] = meshgrid(-(m-1)/2:(m-1)/2, -(n-1)/2:(n-1)/2);
hg = exp(- (h1.^2+h2.^2) / (2*sigma^2));
h = hg ./ sum(hg(:));

h =

0.0030    0.0133    0.0219    0.0133    0.0030
0.0133    0.0596    0.0983    0.0596    0.0133
0.0219    0.0983    0.1621    0.0983    0.0219
0.0133    0.0596    0.0983    0.0596    0.0133
0.0030    0.0133    0.0219    0.0133    0.0030
``````

Observe that this can be done by the built-in `fspecial` as follows:

``````fspecial('gaussian', [m n], sigma)
ans =

0.0030    0.0133    0.0219    0.0133    0.0030
0.0133    0.0596    0.0983    0.0596    0.0133
0.0219    0.0983    0.1621    0.0983    0.0219
0.0133    0.0596    0.0983    0.0596    0.0133
0.0030    0.0133    0.0219    0.0133    0.0030
``````

I think it is straightforward to implement this in any language you like.

EDIT: Let me also add the values of `h1` and `h2` for the given case, since you may be unfamiliar with `meshgrid` if you code in C++.

``````h1 =

-2    -1     0     1     2
-2    -1     0     1     2
-2    -1     0     1     2
-2    -1     0     1     2
-2    -1     0     1     2

h2 =

-2    -2    -2    -2    -2
-1    -1    -1    -1    -1
0     0     0     0     0
1     1     1     1     1
2     2     2     2     2
``````
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I typed [h1,h2] = meshgrid(-(m-1)/2:(m-1)/2, -(n-1)/2:(n-1)/2) and got a h1 ranging from -2 to 2, not from -1.5 to 1.5. Same problem with h2. But my result is the same. Also, why did you use the values of mesh grid as the values in the formula? What does this represent if you were calculating this for an image? –  gsingh2011 Nov 20 '11 at 22:06
You're right! I changed `m` and `n` to 4 in order to see whether the code works and then copied the values for this case instead of giving them for value 5. I've fixed it, thanks. –  petrichor Nov 20 '11 at 22:15
The values are computed on a grid where the one in the center is the origin, which is h1==0 and h2==0 in our case. All the other pairs represent the other coordinates when you look at the h1,h2 values element by element. During filtering, you can think that this grid will be put on a pixel of the image where the origin of the grid is fit exactly on the pixel. You can read Goz's answer in the link you gave in your question for the details. –  petrichor Nov 20 '11 at 22:20

It's as simple as it sounds:

``````double sigma = 1;
int W = 5;
double kernel[W][W];
double mean = W/2;
for (int x = 0; x < W; ++x) for (int y = 0; y < W; ++y)
{
kernel[x][y] = exp( -0.5 * (pow((x-mean)/sigma, 2.0) + pow((y-mean)/sigma,2.0)) )
/ (2 * M_PI * sigma * sigma);
}
``````
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This is flawed: you need to normalize the kernel too, or the image becomes darker depending on W and sigma. simply put: get the sum of kernel values and divide each kernel value by that sum. –  Rookie May 24 '12 at 14:38

To implement the gaussian blur you simply take the gaussian function and compute one value for each of the elements in your kernel.

Usually you want to assign the maximum weight to the central element in your kernel and values close to zero for the elements at the kernel borders. This implies that the kernel should have an odd height (resp. width) to ensure that there actually is a central element.

To compute the actual kernel elements you may scale the gaussian bell to the kernel grid (choose an arbitrary e.g. `sigma = 1` and an arbitrary range e.g. `-2*sigma ... 2*sigma`) and normalize it, s.t. the elements sum to one. To achieve this, if you want to support arbitrary kernel sizes, you will need to compute the sigma in dependence of the kernel size. For example like this Python example shows:

``````from math import exp

def gaussian(x, mu, sigma):
return exp( -(((x-mu)/(sigma))**2)/2.0 )

#kernel_height, kernel_width = 7, 7
kernel_radius = 3 # for an 7x7 filter
sigma = kernel_radius/2. # for [-2*sigma, 2*sigma]

# compute the actual kernel elements
vkernel = [x for x in hkernel]
kernel2d = [[xh*xv for xh in hkernel] for xv in vkernel]

# normalize the kernel elements
kernelsum = sum([sum(row) for row in kernel2d])
kernel2d = [[x/kernelsum for x in row] for row in kernel2d]

for line in kernel2d:
print ["%.3f" % x for x in line]
``````

produces the kernel:

``````['0.001', '0.004', '0.008', '0.010', '0.008', '0.004', '0.001']
['0.004', '0.012', '0.024', '0.030', '0.024', '0.012', '0.004']
['0.008', '0.024', '0.047', '0.059', '0.047', '0.024', '0.008']
['0.010', '0.030', '0.059', '0.073', '0.059', '0.030', '0.010']
['0.008', '0.024', '0.047', '0.059', '0.047', '0.024', '0.008']
['0.004', '0.012', '0.024', '0.030', '0.024', '0.012', '0.004']
['0.001', '0.004', '0.008', '0.010', '0.008', '0.004', '0.001']
``````

or in C++ (untested and a bit longer ...):

``````#include <math.h>
#include <vector>
#include <iostream>
#include <iomanip>
using namespace std;

double gaussian (double x, double mu, double sigma) {
return exp( -(((x-mu)/(sigma))*((x-mu)/(sigma)))/2.0 );
}

vector< vector<double> > produce2dGaussianKernel (int kernelRadius) {
// get kernel matrix
vector< vector<double> > kernel2d ( 2*kernelRadius+1,
);

// determine sigma

// fill values
double sum = 0;
for (int row = 0; row < kernel2d.size(); row++)
for (int col = 0; col < kernel2d[row].size(); col++) {
kernel2d[row][col] = gaussian(row, kernelRadius, sigma) *
sum += kernel2d[row][col];
}

// normalize
for (int row = 0; row < kernel2d.size(); row++)
for (int col = 0; col < kernel2d[row].size(); col++)
kernel2d[row][col] /= sum;

return kernel2d;
}

int main() {
vector< vector<double> > kernel2d = produce2dGaussianKernel (3);
for (int row = 0; row < kernel2d.size(); row++) {
for (int col = 0; col < kernel2d[row].size(); col++)
cout << setprecision(5) << fixed << kernel2d[row][col] << " ";
cout << endl;
}
}
``````

As a simplification you don't need to use a 2d-kernel. More easy to implement and also more efficient to compute is to use two orthogonal 1d-kernels. This is possible due to the associativity of this type of a linear convolution (linear separability). You may also want to see this section of the corresponding wikipedia article.

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