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# Tool to diagonalize large matrices

I want to compute a diffusion kernel, which involves taking exp(b*A) where A is a large matrix. In order to play with values of b, I'd like to diagonalize A (so that exp(A) runs quickly).

My matrix is about 25k x 25k, but is very sparse - only about 60k values are non-zero. Matlab's "eigs" function runs of out memory, as does octave's "eig" and R's "eigen." Is there a tool to find the decomposition of large, sparse matrices?

Dunno if this is relevant, but A is an adjacency matrix, so it's symmetric, and it is full rank.

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Have you tried SVD, `svds` for sparse matrix in matlab.

EDIT: one more thing, don't do full rank SVD since the dimension is big, use a small rank, say 500, so that your solution fits in the memory. This cuts the small eigenvalues and their vectors out. Thus it does not hurt your accuracy much.

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@ A = USV'. S is a square matrix with eigenvaules on the its diagonal. – Yin Zhu May 27 '10 at 0:33
+1 @duffymo: See wikipedia on relationship between svd and eigenvalue decomposition. In any case the OP was asking for diagonalization of A which svd does. – vad May 27 '10 at 0:37
I tried doing this on mine and it said "maximum variable size exceeded." My computer isn't exactly top-of-the-line though, so it could be a problem there instead of with matlab. – Xodarap May 27 '10 at 0:44
@ Xodarap. Matlab's svds is not the best there. You could also try tedlab.mit.edu/~dr/SVDLIBC. When you start, you first make sure SVD does your job by trying small matrices. – Yin Zhu May 27 '10 at 0:48
@Yin - this is an excellent idea, but do you know how much information is lost? I feel like since this is an adjacency matrix and the rows are really quite independent of each other, finding only 10% of the eigenvalues (or whatever) will lose 90% of the info. – Xodarap May 27 '10 at 21:41

Have you considered the following property: exp(A*t) = L^(-1) {(sI-A)^(-1)} where L^(-1) the inverse Laplace transform? - provided that you can invert (sI-A)

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I think inverse laplace runs in O(n^4), which is very slow. It's also prone to errors. See cs.cornell.edu/cv/ResearchPDF/19ways+.pdf – Xodarap May 28 '10 at 17:33

If you have access to a 64 bit machine and octave compiled with 64 bit support, you might be able to get around this problem.

Also, I don't know what platform you are running all of this on, but in UNIX based systems you can use `ulimit` to increase the maximum allowed stack size for user processes.

For example, you can run

``````ulimit -u unlimited
``````

and this will ensure that there are no memory limits etc on your processes. This is not a good idea in general, since you have have runaway processes that will completely bog down your machine. Try instead

``````ulimit -s [stacksize]
``````

to increase the stack size limit.

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Octave has splu which does lu decomposition for sparse matrices. I am not sure whether it can handle 25k x 25k but worth a shot.

Alternatively if your matrix is structured like so: A = [B zeros;zeros C] then you can diagonalize B and C separately and put them together into one matrix. I am guessing you can do something similar for eig.

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Stupid question, but once I do have lu, how do I use this? I realize that det(A) = det(L)*det(U), so there must be some relationship between their diagonalizations, but I'm not smart enough to see it. – Xodarap May 27 '10 at 20:22

In R you could check igraph package and function `arpack` which is interface to ARPACK library.

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