One neat trick you can often use when calculating euclidean distance is to modify your algorithm to work with the *squared* euclidean distance instead - this eliminates a costly square root function that isn't necessary, for example, if you just want to find the largest or smallest distance in a set.

So the inner loop might become:

```
distSquared(j) = sum((des1(i, :) - des2(j, :)).^2);
```

In your case, the tricky thing to change is the line

```
if (vals(1) < distRatio * vals(2))
```

Which is equivalent to

```
if (vals(1)^2 < (distRatio * vals(2))^2)
```

Or

```
if (vals(1)^2 < (distRatio^2) * (vals(2)^2))
```

And if you are getting the values from `distSquared`

instead of `eucl`

, then you could use

```
if (valSquared(1) < (distRatio^2) * valSquared(2))
```

Finally, you could maybe take out the inner loop by rewriting the subtraction like this:

```
countRowsDes2 = size(des2, 1); % this line outside the loop
%... now inside the loop
des1expand = repmat(des1(i, :), countRowsDes2, 1); % copy this row
distSquared = sum((des1expand - des2).^2, 2); % sum horizontally
```

Where I've used `repmat`

to copy the row `des1(i, :)`

, and made `sum`

work on the horizontal dimension using the second dimension argument.

## Putting it all together

```
distRatio = 0.5;
distRatioSq = distRatio^2; % distance ratio squared
countRowsDes1 = size(des1, 1); % number of rows in des1
countRowsDes2 = size(des2, 1); % number of rows in des2
match = zeros(countRowsDes1, 1); % pre-initialize with zeros
for i = i:size(des1, 1)
des1expand = repmat(des1(i, :), countRowsDes2, 1); % copy row i of des1
distSquared = sum((des1expand - des2).^2, 2); % sum horizontally
[valsSquared, index] = sort(distSquared);
if (valsSquared(1) < distRatioSq * valsSquared(2))
match(i) = index(1);
% else zero by initialization
end
```