The usually given answer here is based on `bsxfun`

(cf. e.g. [1]). My proposed approach is based on matrix multiplication and turns out to be much faster than any comparable algorithm I could find:

```
helpA = zeros(numA,3*d);
helpB = zeros(numB,3*d);
for idx = 1:d
helpA(:,3*idx-2:3*idx) = [ones(numA,1), -2*A(:,idx), A(:,idx).^2 ];
helpB(:,3*idx-2:3*idx) = [B(:,idx).^2 , B(:,idx), ones(numB,1)];
end
distMat = helpA * helpB';
```

**Please note:**
For constant `d`

one can replace the `for`

-loop by hardcoded implementations, e.g.

```
helpA(:,3*idx-2:3*idx) = [ones(numA,1), -2*A(:,1), A(:,1).^2, ... % d == 2
ones(numA,1), -2*A(:,2), A(:,2).^2 ]; % etc.
```

**Evaluation:**

```
%% create some points
d = 2; % dimension
numA = 20000;
numB = 20000;
A = rand(numA,d);
B = rand(numB,d);
%% pairwise distance matrix
% proposed method:
tic;
helpA = zeros(numA,3*d);
helpB = zeros(numB,3*d);
for idx = 1:d
helpA(:,3*idx-2:3*idx) = [ones(numA,1), -2*A(:,idx), A(:,idx).^2 ];
helpB(:,3*idx-2:3*idx) = [B(:,idx).^2 , B(:,idx), ones(numB,1)];
end
distMat = helpA * helpB';
toc;
% compare to pdist2:
tic;
pdist2(A,B).^2;
toc;
% compare to [1]:
tic;
bsxfun(@plus,dot(A,A,2),dot(B,B,2)')-2*(A*B');
toc;
% Another method: added 07/2014
% compare to ndgrid method (cf. Dan's comment)
tic;
[idxA,idxB] = ndgrid(1:numA,1:numB);
distMat = zeros(numA,numB);
distMat(:) = sum((A(idxA,:) - B(idxB,:)).^2,2);
toc;
```

Result:

```
Elapsed time is 1.796201 seconds.
Elapsed time is 5.653246 seconds.
Elapsed time is 3.551636 seconds.
Elapsed time is 22.461185 seconds.
```

For a more detailed evaluation w.r.t. dimension and number of data points follow the discussion below (@comments). It turns out that different algos should be preferred in different settings. In non time critical situations just use the `pdist2`

version.

**Further development:**
One can think of replacing the squared euclidean by any other metric based on the same principle:

```
help = zeros(numA,numB,d);
for idx = 1:d
help(:,:,idx) = [ones(numA,1), A(:,idx) ] * ...
[B(:,idx)' ; -ones(1,numB)];
end
distMat = sum(ANYFUNCTION(help),3);
```

Nevertheless, this is quite time consuming. It could be useful to replace for smaller `d`

the 3-dimensional matrix `help`

by `d`

2-dimensional matrices. Especially for `d = 1`

it provides a method to compute the pairwise difference by a simple matrix multiplication:

```
pairDiffs = [ones(numA,1), A ] * [B'; -ones(1,numB)];
```

Do you have any further ideas?

`pdist2`

function? mathworks.com/help/stats/pdist2.html