Hacked into the m-file for `corr2`

to create a customized vectorized version for working with 3D arrays. Proposed here are two approaches with `bsxfun`

(of course!)

**Approach #1**

```
szA = size(A);
szB = size(B);
a1 = bsxfun(@minus,A,mean(mean(A)));
b1 = bsxfun(@minus,B,mean(mean(B)));
sa1 = sum(sum(a1.*a1));
sb1 = sum(sum(b1.*b1));
v1 = reshape(b1,[],szB(3)).'*reshape(a1,[],szA(3));
v2 = sqrt(sb1(:)*sa1(:).');
corr3_out = v1./v2; %// desired output
```

`corr3_out`

stores `corr2`

results between all 3D slices of `A`

and `B`

.

Thus, for `A = rand(4,5,3), B = rand(4,5,6)`

, we would have `corr3_out`

as a `6x3`

array.

**Approach #2**

Slightly different approach to save on few calls to `sum`

and `mean`

by using `reshape`

instead -

```
szA = size(A);
szB = size(B);
dim12 = szA(1)*szA(2);
a1 = bsxfun(@minus,A,mean(reshape(A,dim12,1,[])));
b1 = bsxfun(@minus,B,mean(reshape(B,dim12,1,[])));
v1 = reshape(b1,[],szB(3)).'*reshape(a1,[],szA(3));
v2 = sqrt(sum(reshape(b1.*b1,dim12,[])).'*sum(reshape(a1.*a1,dim12,[])));
corr3_out = v1./v2; %// desired output
```

## Benchmarking

Benchmark code -

```
%// Create random input arrays
N = 55; %// datasize scaling factor
A = rand(4*N,5*N,3*N);
B = rand(4*N,5*N,6*N);
%// Warm up tic/toc
for k = 1:50000
tic(); elapsed = toc();
end
%// Run vectorized and loopy approach codes on the input arrays
%// 1. Vectorized approach
%//... solution code (Approach #2) posted earlier
%// clear variables used
%// 2. Loopy approach
tic
s_A=size(A,3);
s_B=size(B,3);
out1 = zeros(s_B,s_A);
for ii=1:s_A
for jj=1:s_B
out1(jj,ii)=corr2(A(:,:,ii),B(:,:,jj));
end
end
toc
```

Results -

```
-------------------------- With BSXFUN vectorized solution
Elapsed time is 1.231230 seconds.
-------------------------- With loopy approach
Elapsed time is 139.934719 seconds.
```

**MATLAB-JIT lovers show some love here!** :)