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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!

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2 Answers 2

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
share|improve this answer
    
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 don`t 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
1  
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
up vote 0 down vote accepted

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);
cv::Mat tempMask = (h>DBL_EPSILON*maximalVal)/255;
tempMask.convertTo(tempMask,h.type());
cv::multiply(tempMask,h,h);

if (cv::sum(h)[0]!=0){h=h/cv::sum(h)[0];}

cv::Mat h1 = (xx+yy-2*(pow(sigma,2))/(pow(sigma,4));
cv::multiply(h,h1,h1);
h = h1 - cv::sum(h1)[0]/(WinSize*WinSize);
return h;
}
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