# pdf of a particular distribution

I am new to Matlab. I would like to check the so call "logarithmic law" for determinant of random matrices with Matlab, but still do not know how.

Logarithmic law:

Let A be a random Bernoulli matrix (entries are iid, taking value +-1 with prob. 1/2) of size n by n. We may want to compare the probability density function of (log(det(A^2))-log(factorial(n-1)))/sqrt(2n) with the pdf of Gaussian distribution. The logarithmic law says that the pdf of the first will approach to that of the second when n approaches infinity.

My Matlab task is very simple: check the comparison for, say n=100. Anyone knows how to do so?

Thanks.

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pdf is here in Matlab docs. –  darvids0n Aug 29 '11 at 2:02
@H.H.: I did a quick a search on google for "Logarithmic Law for Random Determinants" and found two book references.. I think the last term should be: `sqrt(2*log(n))` –  Amro Aug 29 '11 at 3:06

Consider the following experiment:

``````n = 100;                           %# matrix size
num = 1000;                        %# number of matrices to generate

detA2ln = zeros(num,1);
for i=1:num
A = randi([0 1],[n n])*2 - 1;  %# -1,+1
detA2ln(i) = log(det(A^2));
end

%# `gammaln(n)` is more accurate than `log(factorial(n-1))`
myPDF = ( detA2ln - gammaln(n) ) ./ sqrt(2*log(n));
normplot(myPDF)
``````

Note that for large matrices, the determinant of A*A will be too large to represent in double numbers and will return `Inf`. However we only require the log of the determinant, and there exist other approachs to find this result that keeps the computation in log-scale.

In the comments, @yoda suggested using the eigenvalues `detA2(i) = real(sum(log(eig(A^2))));`, I also found a submission on FEX that have a similar implementation (using LU or Cholesky decomposition)

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Thanks a lot, it works for me. (btw, there was a typo in my formula, the denominator should be sqrt(2*log(n)). –  H. H. Aug 29 '11 at 11:39
Also, is there anyway to check for matrices of larger size? My Matlab works for n=100, but not for n=200, and how about n=1000? The comparison for n=100 seems still unconvincing. –  H. H. Aug 29 '11 at 11:41
@H.H. Replace the last line in the `for` loop with this: `detA2(i) = real(sum(log(eig(A^2))));` This will be slower, but will let you run it for matrices as large as your system/MATLAB will allow. –  yoda Aug 29 '11 at 16:41
@yoda: thanks I added a note how to safely compute the log of the determinant as you suggested –  Amro Aug 29 '11 at 17:30