Given:

```
A_1 = [10 200 7 150]';
A_2 = [0.001 0.450 0.007 0.200]';
```

(As others have already pointed out) There are tools to simply compute correlation, most obviously `corr`

:

```
corr(A_1, A_2); %Returns 0.956766573975184 (Requires stats toolbox)
```

You can also use base Matlab's `corrcoef`

function, like this:

```
M = corrcoef([A_1 A_2]): %Returns [1 0.956766573975185; 0.956766573975185 1];
M(2,1); %Returns 0.956766573975184
```

Which is closely related to the `cov`

function:

```
cov([condition(A_1) condition(A_2)]);
```

As you almost get to in your original question, you can scale and adjust the vectors yourself if you want, which gives a slightly better understanding of what is going on. First create a condition function which subtracts the mean, and divides by the standard deviation:

```
condition = @(x) (x-mean(x))./std(x); %Function to subtract mean AND normalize standard deviation
```

Then the correlation appears to be (A_1 * A_2)/(A_1^2), like this:

```
(condition(A_1)' * condition(A_2)) / sum(condition(A_1).^2); %Returns 0.956766573975185
```

By symmetry, this should also work

```
(condition(A_1)' * condition(A_2)) / sum(condition(A_2).^2); %Returns 0.956766573975185
```

And it does.

I believe, but don't have the energy to confirm right now, that the same math can be used to compute correlation and cross correlation terms when dealing with multi-dimensiotnal inputs, so long as care is taken when handling the dimensions and orientations of the input arrays.

`r`

squared value. – ja72 Jan 15 '13 at 17:10