The approach of @nate (+1) is definitely one possible way of going about this problem. However, the statistician in me is compelled to suggest the following alternative (that does, alas, require the statistics toolbox - but you have this if you have the student version):

Given that your data is Normal (not Multivariate normal), consider using the Jarque-Bera test.

Jarque-Bera tests the null hypothesis that a given dataset is generated by a Normal distribution, versus the alternative that it is generated by some other distribution. If the Jarque-Bera test statistic is less than some critical value, then we fail to reject the null hypothesis.

So how does this help with the goodness-of-fit problem? Well, the larger the test statistic, the more "non-Normal" the data is. The smaller the test statistic, the more "Normal" the data is.

So, assuming you have converted your matrices into two vectors, `A`

and `B`

(each should be 1600 by 1 based on the dimensions you provide in the question), you could do the following:

```
%# Build sample data
A = randn(1600, 1);
B = rand(1600, 1);
%# Perform JB test
[ANormal, ~, AStat] = jbtest(A);
[BNormal, ~, BStat] = jbtest(B);
%# Display result
if AStat < BStat
disp('A is closer to normal');
else
disp('B is closer to normal');
end
```

As a little bonus of doing things this way, `ANormal`

and `BNormal`

tell you whether you can reject or fail to reject the null hypothesis that the sample in `A`

or `B`

comes from a normal distribution! Specifically, if `ANormal`

is 1, then you fail to reject the null (ie the test statistic indicates that `A`

is probably drawn from a Normal). If `ANormal`

is 0, then the data in `A`

is probably not generated from a Normal distribution.

**CAUTION:** The approach I've advocated here is only valid if `A`

and `B`

are the same size, but you've indicated in the question that they are :-)