# Matlab: How to vectorize a nested loop over a 2D set of vectors

I have a function in the following form:

``````function Out = DecideIfAPixelIsWithinAnEllipsoidalClass(pixel,means,VarianceCovarianceMatrix)
ellipsoid = (pixel-means)'*(VarianceCovarianceMatrix^(-1))*(pixel-means);
if ellipsoid <= 1
Out = 1;
else
Out = 0;
end
end
``````

I am doing remote-sensing processes with matlab and I want to classify a LandSatTM images.This picture has 7 bands and is 2048*2048.So I stored them in 3 dimentinal 2048*2048*7 matrix.in this function means is a 7*1 matrix calculated earlier using the sample of the class in a function named ExtractStatisticalParameters and VarianceCovarianceMatrix is a 7*7 matrix in fact you see that:

``````ellipsoid = (pixel-means)'*(VarianceCovarianceMatrix^(-1))*(pixel-means);
``````

is the equation of an ellipsoid.My problem is that each time you can pass a single pixel(it is a 7*1 vector where each row is the value of the pixel in a seperated band) to this function so I need to write a loop like this:

``````for k1=1:2048
for k2=1:2048
pixel(:,1)=image(k1,k2,:);
Out = DecideIfAPixelIsWithinAnEllipsoidalClass(pixel,means,VarianceCovarianceMatrix);
end
end
``````

and you know it will take alot of time and energy of the system.Can you suggest me a way to reduce the pressure applied on the systam?

-

No need for loops!

``````pMinusMean = bsxfun( @minus, reshape( image, [], 7 ), means' ); %//' subtract means from all pixes
iCv = inv( arianceCovarianceMatrix );
ell = sum( (pMinusMean * iCv ) .* pminusMean, 2 ); % note the .* the second time!
Out = reshape( ell <= 1, size(image(:,:,1)) ); % out is 2048-by-2048 logical image
``````

### Update:

After a (somewhat heated) debate in the comments below I add a correction made by Rody Oldenhuis:

``````pMinusMean = bsxfun( @minus, reshape( image, [], 7 ), means' ); %//' subtract means from all pixes
ell = sum( (pMinusMean / varianceCovarianceMatrix ) .* pminusMean, 2 ); % note the .* the second time!
Out = reshape( ell <= 1, size(image(:,:,1)) );
``````

The key issue in this change is that Matlab's `inv()` is poorly implemented and it is best to use `mldivide` and `mrdivide` (operators `/` and `\`) instead.

-
...did you just use `inv()` to solve a linear system? Near the top of `doc inv`: "In practice, it is seldom necessary to form the explicit inverse of a matrix. A frequent misuse of `inv` arises when solving the system of linear equations `Ax = b`. One way to solve this is with `x = inv(A)*b`. A better way, from both an execution time and numerical accuracy standpoint, is to use the matrix division operator `x = A\b`. This produces the solution using Gaussian elimination, without forming the inverse. See `mldivide` (``) for further information." –  Rody Oldenhuis Jun 17 '13 at 21:15
@RodyOldenhuis `inv` is NOT used for solving systems of equations in this question, it is used as the covariance matrix of a gaussian (ellipsoid). –  Shai Jun 17 '13 at 21:22
euhmmm...so? What prevents you from writing `sum( pMinusMean/varianceCovarianceMatrix .* pminusMean, 2)`? –  Rody Oldenhuis Jun 17 '13 at 21:31
@Shai: Well that wasn't really my intention, but thanks :) It's not that it's "poorly implemented", it's just that no algorithms exist that are as fast and accurate as the ones you can use to compute the products `inv(A)*x` or `x*inv(A)`. Sorry if I come off a bit strong about this issue, but when you see people use `i` or `j` as a variable name, what would you do? :) I'm saying that it's nice to implement a bubble-sort or bogosort for educational reasons once or twice, but really, in the end what you should use and teach is quicksort (and similar) -- same with `inv()`. –  Rody Oldenhuis Jun 18 '13 at 14:41
You comment wasn't about `A*X = B`, but rather that one should NEVER use `inv`. I don't don't like blanket statements. As you say, teaching new users why things work one way or another and what the trade-offs are is better than just saying "NEVER." As is mentioned, `inv` is a simple function that has speed advantages in some cases. Precision down to `eps` is not always desired as long as one understands the numerics of a particular problem. "Best" does not always mean most accurate. `trace(A\eye(size(A)))` takes 50% longer than `trace(inv(A))` for large random matrices on my machine. –  horchler Jun 18 '13 at 14:49