1

The problem is a s following, how to approximate a Gaussian Blur Filter with a given STD using Box Blur / Extended Box Blur.

More specifically, I know this is the way Photoshop applies its Gaussian Blur.

First, an article about "Extended Box Blur can be seen here - Theoretical Foundations of Gaussian Convolution by Extended Box Filtering.

The problem I'm having is with Figure 2 in the article.
The best way to explain this would be using an example.

Let's say we need to approximate a Gaussian Blur with STD of 15.4 -> Var = 237.16.
In order to have a good approximation we'll do that with 6 iterations of a Box Blur.

Now, How do I choose the length of the Box Blur (We'll do it in a separable manner, namely, working in 1D)?
Should I chose different lengths (It seems I have to)?
The target is matching the GB Level of Blur (Which is its STD / VAR).

Thank You.

P.S.
I'm working on MATLAB, so code is easy :-).

2
  • These are actually multiple questions. If you could include a (nearly) working code example in the question that could help a lot. May 7 '14 at 15:42
  • @DennisJaheruddin, I think I solved it for Fixed Length Box Blur. I will share the MATLAB code later.
    – Royi
    May 7 '14 at 19:17
0

This is my MATLAB implementation of the article:

```

function [ vBoxBlurKernel ] = GenerateBoxBlurKernel( boxBlurVar, numIterations )
% ----------------------------------------------------------------------------------------------- %
% [ boxBlurKernel ] = GenerateBoxBlurKernel( boxBlurVar, numIterations )
%   Approximates 1D Gaussian Kernel by iterative convolutions of "Extended Box Filter".
% Input:
%   - boxBlurVar        -   BoxFilter Varaiance.
%                           The variance of the output Box Filter.
%                           Scalar, Floating Point (0, inf).
%   - numIterations     -   Number of Iterations.
%                           The number of convolution iterations in order
%                           to produce the output Box Filter.
%                           Scalar, Floating Point [1, inf), Integer.
% Output:
%   - vBoxBlurKernel    -   Output Box Filter.
%                           The Box Filter with 'boxBlurVar' Variance.
%                           Vector, Floating Point, (0, 1).
% Remarks:
%   1.  The output Box Filter has a variance of '' as if it is treated as
%       Discrete Probability Function.
%   2.  References: "Theoretical Foundations of Gaussian Convolution by Extended Box Filtering"
%   3.  Prefixes:
%       -   'm' - Matrix.
%       -   'v' - Vector.
% TODO:
%   1.  F
%   Release Notes:
%   -   1.0.001     07/05/2014  xxxx xxxxxx
%       *   Accurate calculation of the "Extended Box Filter" length as in
%           the reference.
%   -   1.0.000     06/05/2014  xxxx xxxxxx
%       *   First release version.
% ----------------------------------------------------------------------------------------------- %

boxBlurLength = sqrt(((12 * boxBlurVar) / numIterations) + 1);
boxBlurRadius = (boxBlurLength - 1) / 2;

% 'boxBlurRadiusInt' -> 'l' in the reference
boxBlurRadiusInt    = floor(boxBlurRadius);
% boxBlurRadiusFrac   = boxBlurRadius - boxBlurRadiusInt;

% The length of the "Integer" part of the filter.
% 'boxBlurLengthInt' -> 'L' in the reference
boxBlurLengthInt = 2 * boxBlurRadiusInt + 1;

a1 = ((2 * boxBlurRadiusInt) + 1);
a2 = (boxBlurRadiusInt * (boxBlurRadiusInt + 1)) - ((3 * boxBlurVar) / numIterations);
a3 = (6 * ((boxBlurVar / numIterations) - ((boxBlurRadiusInt + 1) ^ 2)));

alpha = a1 * (a2 / a3);
ww = alpha / ((2 * boxBlurRadiusInt) + 1 + (2 * alpha));

% The length of the "Extended Box Filter".
% 'boxBlurLength' -> '\Gamma' in the reference.
boxBlurLength = (2 * (alpha + boxBlurRadiusInt)) + 1;

% The "Single Box Filter" with Varaince - boxBlurVar / numIterations
% It is normalized by definition.
vSingleBoxBlurKernel = [ww, (ones(1, boxBlurLengthInt) / boxBlurLength), ww];
% vBoxBlurKernel = vBoxBlurKernel / sum(vBoxBlurKernel);

vBoxBlurKernel = vSingleBoxBlurKernel;

% singleBoxKernelVar = sum(([-(boxBlurRadiusInt + 1):(boxBlurRadiusInt + 1)] .^ 2) .* boxBlurKernel)
% boxKernelVar = numIterations * singleBoxKernelVar


for iIter = 2:numIterations
    vBoxBlurKernel = conv2(vBoxBlurKernel, vSingleBoxBlurKernel, 'full');
end


end

Here's a demo to try it:

% Box Blur Demo

gaussianKernelStd = 9.6;
gaussianKernelVar = gaussianKernelStd * gaussianKernelStd;
gaussianKernelRadius = ceil(6 * gaussianKernelStd);
gaussianKernel = exp(-([-gaussianKernelRadius:gaussianKernelRadius] .^ 2) / (2 * gaussianKernelVar));
gaussianKernel = gaussianKernel / sum(gaussianKernel);

boxBlurKernel = GenerateBoxBlurKernel(gaussianKernelVar, 6);
boxBlurKernelRadius = (length(boxBlurKernel) - 1) / 2;

figure();
plot([-gaussianKernelRadius:gaussianKernelRadius], gaussianKernel, [-boxBlurKernelRadius:boxBlurKernelRadius], boxBlurKernel);

sum(([-boxBlurKernelRadius:boxBlurKernelRadius] .^ 2) .* boxBlurKernel)
sum(([-gaussianKernelRadius:gaussianKernelRadius] .^ 2) .* gaussianKernel)

The tricky part is the calculation of the effective length of the "Extended Box Filter".
It's not the length by the calculation of the length using the variance of a regular "Box Filter".

The article is great and this method is amazing.

4
  • How to implement with 2D gaussian kernel. Example, I have a code to generate 2D gaussian: Ksigma=fspecial('gaussian',round(2*sigma)*2 + 1,sigma); % kernel. Could you use boxfilter to approximate my Ksigma kernel? Thank you
    – John
    Jul 31 '14 at 16:32
  • Gaussian Filter is separable. Use that property to implement it by 2 1D Gaussian filters.
    – Royi
    Aug 1 '14 at 7:21
  • Just apply 1D Gaussian on the Rows and then on the Columns.
    – Royi
    Aug 1 '14 at 8:19
  • I=zeros(512,512); I(256,256)=1; for i=1:512 I_row=I(:,i);I_row_f=GenerateBoxBlurKernel(I_row, 6 ); I_col=I(i,:); GenerateBoxBlurKernel(I_col, 6 ); end I_2D=sqrt(I_row.^2+I_col.^2); Is it correct?
    – John
    Aug 1 '14 at 8:29

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.