As you can see looking at the source, in the simplest case with no masks, and N
variables with M
samples each, it returns the (N, N)
covariance matrix calculated as:
(x-m) * (x-m).T.conj() / (N - 1)
Where the *
represents the matrix product[1]
Implemented roughly as:
X -= X.mean(axis=0)
N = X.shape[1]
fact = float(N - 1)
return dot(X, X.T.conj()) / fact
If you want to review the source, look here instead of the link from Mr E unless you're interested in masked arrays. As you mentioned, the documentation isn't great.
[1] which in this case is effectively (but not exactly) the outer product because (x-m)
has N
column vectors of length M
and thus (x-m).T
is as many row vectors. The end result is the sum of all the outer products. The same *
will give the inner (scalar) product if the order is reversed. But, technically these are both just standard matrix multiplications and the true outer product is only the product of a column vector onto a row vector.