Use **pdist2** or pdist. Note that pdist2 from Matlab is just slow...

Code:

```
X = rand(100, 3);
K = squareform(pdist(X, 'euclidean'));
K = exp(-K.^2);
```

I'll write this for the more general case where you have *two* matrices and you want to find all the distances.
`(x-y)^2 = x'x - 2x'y + y'y`

If you want to compute the Gram matrix, you need all combinations of differences.

```
X = rand(100, 3);
Y = rand(50, 3);
A = sum(X .* X, 2);
B = -2 *X * Y';
C = sum(Y .* Y, 2);
K = bsxfun(@plus, A, B);
K = bsxfun(@plus, K, C);
K = exp(-K);
```

# EDIT: Speed-comparison

## Code

```
% http://stackoverflow.com/questions/13109826/compute-a-gramm-matrix-in-matlab-without-loops/24407122#24407122
function time_gramm()
% I have a matrix X(10000, 800). I want to compute gramm matrix K(10000,10000), where K(i,j)= exp(-(X(i,:)-X(j,:))^2).
X = rand(100, 800);
%% The straight-forward pdist solution.
tic;
K = squareform(pdist(X, 'euclidean'));
K1 = exp(-K .^2);
t1 = toc;
fprintf('pdist took \t%d seconds\n', t1);
%% The vectorized solution
tic;
A = sum(X .* X, 2);
B = -2 * X * X';
K = bsxfun(@plus, A, B);
K = bsxfun(@plus, K, A');
K2 = exp(-K);
t2 = toc;
fprintf('Vectorized solution took \t%d seconds.\n', t2);
%% The not-so-smart triple-loop solution
tic;
N = size(X, 1);
K3 = zeros(N, N);
for i=1:N
% fprintf('Running outer loop for i= %d\n', i);
for j=1:N
xij = X(i,:) - X(j,:);
xij = norm(xij, 2);
xij = xij ^ 2;
K3(i,j) = -xij;
% d = X(i,:) - X(j,:); % Alternative way, twice as fast but still
% orders of magnitude slower than the other solutions.
% K3(i,j) = exp(-d * d');
end
end
K3 = exp(K3);
t3 = toc;
fprintf('Triple-nested loop took \t%d seconds\n', t3);
%% Assert results are the same...
assert(all(abs(K1(:) - K2(:)) < 1e-6 ));
assert(all(abs(K1(:) - K3(:)) < 1e-6 ));
end
```

## Results

I ran the above code with N=100

```
pdist took 8.600000e-03 seconds
Vectorized solution took 3.916000e-03 seconds.
Triple-nested loop took 2.699330e-01 seconds
```

Notice that at 100th the requested size of the question, the performance of the code suggested in the other answer (`O(m^2 n)`

) is two orders of magnitude slower. By the time, I plugged in 100k as the size of the `X`

matrix, it took much, much longer than I cared to wait.

The performance on the full-sized problem (`X = rand(10000, 800)`

) was this:

```
pdist took 5.470632e+01 seconds
Vectorized solution took 1.141894e+01 seconds.
```

## Comment

The vectorized solution took 11s, Matlab's pdist took 55s and the manual solution suggested in the other sample never finished.

`D`

, which is not defined. There is also not exponent there, while you have exp in the first code line. Gram matrix looks like all possible inner products of vectors. Why do you calculate exp? – angainor Oct 28 '12 at 15:03