# Sparse large linear system in matlab (out of memory)?

I have programmed the gauss-seidel method but i have to "call" this to solve a nxn Ax=b system where n is 100.000 . Also A(i,i)=3 , A(i-1,i)=A(i+1,i)=-1 and everywhere else we have zeros,concerning b=[2 1 1 1 1 1 .... 1 2]' (first and last elements are 2).

I also have programmed a function to test for n=100 , where i've made a special LU decomposition of A but when i'm trying to call the same function for n=100.000 it says out of memory. How i could use gauss-seidel for n=100.000 without the out of memory message ? I can't think of a nice algorithm in order to use only the nonzero elements of A and i'm a matlab newbie ...

Here's the code for the n=100 http://pastebin.com/U0vAheMD

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It might be helpful for you to take a look at the spdiags command which is helpful for generating large sparse matrices. –  johnish Dec 23 '12 at 9:27

The simplest way is to use sparse matrices. But the more convenient way is to use Tridiagonal matrix algorithm, for which you will not even have to store the matrix since you only have -1 and 3 in it. However, I believe using sparse matrix will be the same efficient since Mathworks did a great job on optimizing their linear solvers for different cases.

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I see no reason for using decomposition for you task, at least from you description. –  Mikhail Dec 23 '12 at 7:50
@iz - I guess you'll have to re-write your GS code for sparse matrices. –  Shai Dec 23 '12 at 7:54
Actually, the MORE convenient way is to use the capabilities for sparse matrices. That way the user need not program explicit solvers for specific cases. –  user85109 Dec 23 '12 at 15:19

If you have not explicitly created a sparse matrix, then MATLAB has no idea that it is sparse. That it has a lot of zeros is irrelevant. It is time for you to start learning how to actually USE sparse matrices.

``````help sparse
help spdiags
``````

In fact, once your matrix is stored in sparse form, there is no need to write your own LU code anyway. There never was a need, except to satisfy a homework problem.

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