# Covariance matrix computation

Input : random vector X=xi, i=1..n.
vector of means for X=meanxi, i=1..n
Output : covariance matrix Sigma (n*n).
Computation :
1) find all cov(xi,xj)= 1/n * (xi-meanxi) * (xj-meanxj), i,j=1..n
2) Sigma(i,j)=cov(xi,xj), symmetric matrix.
Is this algorithm correct and has no side-effects?

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The problem statement is not very clear. Do you really have one single vector as input? Do the xi all have the same mean? Why would you divide by (n-1) when calculating the mean? –  Henrik Jul 22 '10 at 8:54
In theory i have a lot of them (X is actually some process X(t)) where t is [0..k], but during modeling i'm interested only in case k=kmax, that's why i get single vector X(kmax)=X which consists of r numbers. n-1 is correction, doesn't affect much. About means - they are different as i see now. –  Singularity Jul 22 '10 at 11:05

Each `xi` should be a vector (random variable) with it's own variance and mean.

Covariance matrix is symmetric, so you just need to compute one half of it (and copy the rest) and has variance of xi at main diagonal.

`````` S = ...// your symmetric matrix n*n
for(int i=0; i<n;i++)
S(i,i) = var(xi);
for(j = i+1; j<n; j++)
S(i,j) = cov(xi, xj);
S(j,i) = S(i,j);
end
end
``````

where variance (var) of xi:

``````v = 0;
for(int i = 0; i<xi.Count; i++)
v += (xi(i) - mean(xi))^2;
end
v = v / xi.Count;
``````

and covariance (cov)

``````cov(xi, xj) = r(xi,xj) * sqrt(var(xi)) * sqrt(var(xj))
``````

where `r(xi, xj)` is Pearson product-moment correlation coefficient

EDIT
or, since cov(X, Y) = E(X*Y) - E(X)*E(Y)

``````cov(xi, xj) = mean(xi.*xj) - mean(xi)*mean(xj);
``````

where `.*` is Matlab-like element-wise multiplication.
So if `x = [x1, x2]`, `y = [y1, y2]` then `z = x.*y = [x1*y1, x2*y2]`;

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The diagonal contains the variances. –  Henrik Jul 22 '10 at 9:34
Yes, you are right. Corrected –  Gacek Jul 22 '10 at 9:36
Why do you define covariance in terms of correlation? Usually it's done the other way round. –  Henrik Jul 22 '10 at 9:52
@Gacek: I agree with Henrik. What you have written is correct, however, the correlation is defined in terms of covariance, so it is redundant to calculate the correlation and then obtain covariance from it. –  Il-Bhima Jul 22 '10 at 11:01
Since i've brought vector of means back (was computed previously, i missed that), variance is computed easily as sum(x(i)-mean(i)/n). Now what about covariance itself - are there any ways to compute it simpler? Btw, in your formula sj is mis-typed xj i guess. –  Singularity Jul 22 '10 at 11:59