# MATLAB: Correlation with a seed region

By default, all built-in functions for computing correlation or covariance return a matrix. I am trying to write an efficient function that will compute the correlation between a seed region and various other regions, but I do not need the correlations between the other regions. I assume that computing the full correlation matrix would therefore be inefficient.

I could instead compute a the correlation matrix between each region and the seed region, choose one of the off diagonal points and store it, but I feel like looping in this situation is also inefficient.

To be more concrete, each point in my 3-dimensional space has a time dimension. I am attempting to compute the mean correlation between a given point and all points in space within a given radius. I want to repeat this procedure hundreds of thousands of times, for many different radius lengths, and so on, so I would like for this to be as efficient as possible.

So, what is the best way to compute the correlation between a single vector and several others, without computing correlations that I will just ignore?

Thank you, Chris

EDIT: Here is my code now...

``````function [corrMap] = TIME_meanCorrMap(A,radius)
% Even though the variable is "radius", we work with cubes for simplicity...
% So, the radius is the distance (in voxels) from the center of the cube an edge.
dim = size(A);
corrMap = zeros(dim(1:3));
corrCoefs = zeros(1,denom);
seed = A(x,y,z,:);
i=0;
for xx = rx
for yy = ry
for zz = rz
if ~all([x y z] == [xx yy zz])
i = i + 1;
temp = corrcoef(seed,A(xx,yy,zz,:));
corrCoeffs(i) = temp(1,2);
end
end
end
end
corrMap = mean(corrCoeffs);
end
end
end
``````

EDIT: Here are some more times to supplement the accepted answer. Using bsxfun() to do normalization, and matrix multiplication to compute correlations:

``````tic; for i=1:10000
x=rand(100);
xz = bsxfun(@rdivide,bsxfun(@minus,x,mean(x)),std(x));
cc = xz(:,2:end)' * xz(:,1) ./ 99;
end; toc
Elapsed time is 6.928251 seconds.
``````

Using zscore() to normalize, matrix multiplication to compute correlations:

``````tic; for i=1:10000
x=rand(100);
xz = zscore(x);
cc = xz(:,2:end)' * xz(:,1) ./ 99;
end; toc
Elapsed time is 7.040677 seconds.
``````

Using bsxfun() to normalize, and corr() to compute correlations.

``````tic; for i=1:10000
x=rand(100);
xz = bsxfun(@rdivide,bsxfun(@minus,x,mean(x)),std(x));
cc = corr(x(:,1),x(:,2:end));
end; toc
Elapsed time is 11.385707 seconds.
``````
-

It is certainly possible to improve upon the `for` loop that you are currently employing. The correlation compuattions can be parallelized using matrix multiplications if you have sufficient RAM. However, it will require you to unwrap your 4-dimensional data matrix A into a different shape. most likely you are dealing with 3-dimensional voxelwise fMRI data, in which case you'll have to reshape from [x y z time] matrix to an [index time] matrix. I will assume you can deal with that reshaping. Once you have your `seed` timecourse [Time by 1] and your `target` timecourses [Time by NumTargets] ready, you can perform some much more efficient computations.

A quick way to efficiently compute the desired correlation is using the `corr` function in MATLAB. This function will accept 2 matrix arguments and it will quite efficiently compute all pairwise correlations between the columns of argument 1 and the columns of argument 2, e.g.

``````T = 200; %time samples
N = 20;  %number of other voxels

seed = randn(T,1);     %data from seed voxel
targets = randn(T,N);  %data from target voxels

%here is the for loop method
tic
for n = 1:N
tmp = corrcoef(seed, targets(:,n));
tmpcc = tmp(1,2);
end
looptime = toc;

%here is the parallel method
tic
cc = corr(seed, targets);
matrixtime = toc;
``````

On my machine, the parallel operation in `corr` is faster than the loop method by a factor proportional to T*N.

It is possible to go a little faster than the `corr` function if you are willing to perofrm the underlying matrix operations yourself, and in any case it is worth knowing what they are. The correlation between two vectors is basically a normalized dot product, so using the conventions above you can compute the correlations in the following way

``````zseed = zscore(seed);  %normalize the seed timecourse by z-scoring
ztargets= zscore(targets);  %normalize the target timecourses by z-scoring
ztargets = ztargets';      %flip columns and rows for convenience
cc2 = ztargets*zseed./(T-1);    %compute many dot products with one matrix multiplication
``````

The code above is basically what the `corr` function will do which is why it is much faster than the loop. Note that most of the operation time is in the `zscore` operations, and you can improve on the performance of the `corr` function if you efficiently compute the `zscore` using the `bsxfun` command. For now, I hope this gives you some direction on how to compute a correlation between a seed timecourse and many target timecourses without having to loop through and compute each one separately.

-
This was extremely helpful, thank you! And the fact that you deduced the nature of my data from just my description and code was a nice added touch. – Chris Cox Sep 16 '12 at 16:42
Well, I have worked on similar problems in the past, so it was not too unlikely a guess. Glad to help! – cjh Sep 16 '12 at 19:45