# create 2D LoG kernel in openCV like fspecial in Matlab

My question is not how to filter an image using the laplacian of gaussian (basically using filter2D with the relevant kernel etc.).

What I want to know is how I generate the NxN kernel.

I'll give an example showing how I generated a [Winsize x WinSize] Gaussian kernel in openCV.

In Matlab:

gaussianKernel = fspecial('gaussian', WinSize, sigma);


In openCV:

cv::Mat gaussianKernel = cv::getGaussianKernel(WinSize, sigma, CV_64F);
cv::mulTransposed(gaussianKernel,gaussianKernel,false);


Where sigma and WinSize are predefined.

I want to do the same for a Laplacian of Gaussian.

In Matlab:

LoGKernel = fspecial('log', WinSize, sigma);


How do I get the exact kernel in openCV (exact up to negligible numerical differences)?

I'm working on a specific application where I need the actual kernel values and simply finding another way of implementing LoG filtering by approximating Difference of gaussians is not what I'm after.

Thanks!

-

You can generate it manually, using formula

LoG(x,y) = (1/(pi*sigma^4)) * (1 - (x^2+y^2)/(sigma^2))* (e ^ (- (x^2 + y^2) / 2sigma^2)

http://homepages.inf.ed.ac.uk/rbf/HIPR2/log.htm

cv::Mat kernel(WinSize,WinSize,CV_64F);
int rows = kernel.rows;
int cols = kernel.cols;
double halfSize = (double) WinSize / 2.0;
for (size_t i=0; i<rows;i++)
for (size_t j=0; j<cols;j++)
{
double x = (double)j - halfSize;
double y = (double)i - halfSize;
kernel.at<double>(j,i) = (1.0 /(M_PI*pow(sigma,4))) * (1 - (x*x+y*y)/(sigma*sigma))* (pow(2.718281828, - (x*x + y*y) / 2*sigma*sigma));
}


If function above is not OK, you can simply rewrite matlab version of fspecial:

 case 'log' % Laplacian of Gaussian
% first calculate Gaussian
siz   = (p2-1)/2;
std2   = p3^2;

[x,y] = meshgrid(-siz(2):siz(2),-siz(1):siz(1));
arg   = -(x.*x + y.*y)/(2*std2);

h     = exp(arg);
h(h<eps*max(h(:))) = 0;

sumh = sum(h(:));
if sumh ~= 0,
h  = h/sumh;
end;
% now calculate Laplacian
h1 = h.*(x.*x + y.*y - 2*std2)/(std2^2);
h     = h1 - sum(h1(:))/prod(p2); % make the filter sum to zero

-
I am familiar with the formula (funny enough, I saw the webpage you're referring to before submitting the question). I just don't know how to go about actually computing it in C++ (or, better yet, directly to an openCV cv::Mat). Would you suggest computing one quarter of the matrix (as it is completely symmetrical about the center) using 2 for loops where the indices serve as x,y distance and then mirror the result twice (to convert one quarter to a whole kernel)? –  ComputerVisioner May 5 at 12:27
I have added basic example how to compute. Do you have so big matrices that you could not afford to do a simple loop? And it looks like you dont need "how to generate kernel", but "how to do basic operations in OpenCV" -- look prism.gatech.edu/~ahuaman3/docs/OpenCV_Docs/tutorials/basic_0/… –  old-ufo May 5 at 12:49
Declare halfSize as float halfSize = float(WinSize) /2;. Do the same with x and y. Otherwise, the center of your LoG will be rounded to the nearest pixel. This can be crappy if using a small sized kernel. –  KeillRandor May 5 at 13:15
Thanks. My technical openCV level (though not apparent by this question which was written after very little sleep lately :) ) is quite a bit higher than you assume. The solution you gave is something I've also tried - it definitely does not yield similar results to matlab at all. –  ComputerVisioner May 5 at 13:17
Probably, you might edit your question to make clearer the core of the problem. Also - have you looked into matlab fspecial function? –  old-ufo May 5 at 13:35

I want to thank old-ufo for nudging me in the correct direction. I was hoping I won't have to reinvent the wheel by doing a quick matlab-->openCV conversion but guess this is the best solution I have for a quick solution.

NOTE - I did this for square kernels only (easy to modify otherwise, but I have no need for that so...). Maybe this can be written in a more elegant form but is a quick job I did so I can carry on with more pressing matters.

From main function:

int WinSize(7); int sigma(1); // can be changed to other odd-sized WinSize and different sigma values
cv::Mat h = fspecialLoG(WinSize,sigma);


And the actual function is:

// return NxN (square kernel) of Laplacian of Gaussian as is returned by     Matlab's: fspecial(Winsize,sigma)
cv::Mat fspecialLoG(int WinSize, double sigma){
// I wrote this only for square kernels as I have no need for kernels that aren't square
cv::Mat xx (WinSize,WinSize,CV_64F);
for (int i=0;i<WinSize;i++){
for (int j=0;j<WinSize;j++){
xx.at<double>(j,i) = (i-(WinSize-1)/2)*(i-(WinSize-1)/2);
}
}
cv::Mat yy;
cv::transpose(xx,yy);
cv::Mat arg = -(xx+yy)/(2*pow(sigma,2));
cv::Mat h (WinSize,WinSize,CV_64F);
for (int i=0;i<WinSize;i++){
for (int j=0;j<WinSize;j++){
h.at<double>(j,i) = pow(exp(1),(arg.at<double>(j,i)));
}
}
double minimalVal, maximalVal;
minMaxLoc(h, &minimalVal, &maximalVal);
`