# generation of normally distributed random vector with covariance matrix

In matlab it is easy to generate a normally distributed random vector with a mean and a standard deviation. From the help randn:

Generate values from a normal distribution with mean 1 and standard deviation 2. r = 1 + 2.*randn(100,1);

Now I have a covariance matrix C and I want to generate N(0,C).

But how could I do this?

From the randn help: Generate values from a bivariate normal distribution with specified mean vector and covariance matrix. mu = [1 2]; Sigma = [1 .5; .5 2]; R = chol(Sigma); z = repmat(mu,100,1) + randn(100,2)*R;

But I don't know exactly what they are doing here.

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Which part do you not understand? `mu` is the mean vector (in your case 0, so leave it off), `Sigma` is the covariance matrix, and they're generating 100 pairs of random numbers. – Donnie Dec 6 '10 at 16:05
I don't understand the repmat part. Is it also possible to do it this way: chol(C, 'lower') + randn(N,1); with C the covariance matrix – Derk Dec 6 '10 at 16:32
Sorry, I think I do understand now. The repmat is used to build a mean matrix for 100 pairs of random numbers. – Derk Dec 6 '10 at 16:35
you can use the MVNRND function from the Statistics Toolbox, see this related question: stackoverflow.com/questions/4041866/gaussian-basis-function – Amro Dec 7 '10 at 10:38
@Donnie or Amro : you should post an answer so Derk can accept it and this question will be archived for anyone to consult :) – ibiza Dec 15 '10 at 20:39

This is somewhat a math question, not a programming question. But I'm a big fan of writing great code that requires both solid math and programming knowledge, so I'll write this for posterity.

You need to take the Cholesky decomposition (or any decomposition/square root of a matrix) to generate correlated random variables from independent ones. This is because if `X` is a multivariate normal with mean `m` and covariance `D`, then `Y = AX` is a multivariate normal with mean `Am` and covariance matrix `ADA'` where `A'` is the transpose. If `D` is the identity matrix, then the covariance matrix is just `AA'` which you want to be equal to the covariance matrix `C` you are trying to generate.

The Cholesky decomposition computes such a matrix `A` and is the most efficient way to do it.

``````mvnrnd(mu,SIGMA)