# Approach #1

For a `N x 2`

sized points/pixels array, you can avoid `permute`

as suggested in the other solution by Luis, which could slow down things a bit, to have a kind of `"permute-unrolled"`

version of it and also let's `bsxfun`

work towards a `2D`

array instead of a `3D`

array, which must be better with performance.

Thus, assuming clusters to be ordered as a `N x 2`

sized array, you may try this other `bsxfun`

based approach -

```
%// Get a's and b's
im_a = im(:,:,2);
im_b = im(:,:,3);
%// Get the minimum indices that correspond to the cluster IDs
[~,idx] = min(bsxfun(@minus,im_a(:),clusters(:,1).').^2 + ...
bsxfun(@minus,im_b(:),clusters(:,2).').^2,[],2);
idx = reshape(idx,size(im,1),[]);
```

# Approach #2

You can try out another approach that leverages `fast matrix multiplication in MATLAB`

and is based on this smart solution -

```
d = 2; %// dimension of the problem size
im23 = reshape(im(:,:,2:3),[],2);
numA = size(im23,1);
numB = size(clusters,1);
A_ext = zeros(numA,3*d);
B_ext = zeros(numB,3*d);
for id = 1:d
A_ext(:,3*id-2:3*id) = [ones(numA,1), -2*im23(:,id), im23(:,id).^2 ];
B_ext(:,3*id-2:3*id) = [clusters(:,id).^2 , clusters(:,id), ones(numB,1)];
end
[~, idx] = min(A_ext * B_ext',[],2); %//'
idx = reshape(idx, size(im,1),[]); %// Desired IDs
```

## What’s going on with the matrix multiplication based distance matrix calculation?

Let us consider two matrices `A`

and `B`

between whom we want to calculate the distance matrix. For the sake of an easier explanation that follows next, let us consider `A`

as `3 x 2`

and `B`

as `4 x 2`

sized arrays, thus indicating that we are working with X-Y points. If we had `A`

as `N x 3`

and `B`

as `M x 3`

sized arrays, then those would be `X-Y-Z`

points.

Now, if we have to manually calculate the first element of the square of distance matrix, it would look like this –

```
first_element = ( A(1,1) – B(1,1) )^2 + ( A(1,2) – B(1,2) )^2
```

which would be –

```
first_element = A(1,1)^2 + B(1,1)^2 -2*A(1,1)* B(1,1) + ...
A(1,2)^2 + B(1,2)^2 -2*A(1,2)* B(1,2) … Equation (1)
```

Now, according to our proposed matrix multiplication, if you check the output of `A_ext`

and `B_ext`

after the loop in the earlier code ends, they would look like the following –

So, if you perform matrix multiplication between `A_ext`

and transpose of `B_ext`

, the first element of the product would be the sum of elementwise multiplication between the first rows of `A_ext`

and `B_ext`

, i.e. sum of these –

The result would be identical to the result obtained from `Equation (1)`

earlier. This would continue for all the elements of `A`

against all the elements of `B`

that are in the same column as in `A`

. Thus, we would end up with the complete squared distance matrix. That’s all there is!!

## Vectorized Variations

Vectorized variations of the matrix multiplication based distance matrix calculations are possible, though there weren't any big performance improvements seen with them. Two such variations are listed next.

**Variation #1**

```
[nA,dim] = size(A);
nB = size(B,1);
A_ext = ones(nA,dim*3);
A_ext(:,2:3:end) = -2*A;
A_ext(:,3:3:end) = A.^2;
B_ext = ones(nB,dim*3);
B_ext(:,1:3:end) = B.^2;
B_ext(:,2:3:end) = B;
distmat = A_ext * B_ext.';
```

**Variation #2**

```
[nA,dim] = size(A);
nB = size(B,1);
A_ext = [ones(nA*dim,1) -2*A(:) A(:).^2];
B_ext = [B(:).^2 B(:) ones(nB*dim,1)];
A_ext = reshape(permute(reshape(A_ext,nA,dim,[]),[1 3 2]),nA,[]);
B_ext = reshape(permute(reshape(B_ext,nB,dim,[]),[1 3 2]),nB,[]);
distmat = A_ext * B_ext.';
```

So, these could be considered as experimental versions too.

`bsxfun`

, the most versatile tool for vectorization! – Divakar Nov 19 '14 at 12:52