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I'm working on a program in which I have a banded matrix M and a vector b, and I want to maintain an approximate solution vector x such that Mxb. Is there a speedy algorithm or way of modeling this so that I can change individual elements of M and correspondingly update x, without having to do a full matrix inversion?

One thing I'm considering is maintaining an approximate inverse of M, using the Sherman Morrison Algorithm in combination with a fast approximate matrix multiplication algorithm like these 1 2 3.

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What are the dimensions of M? How sparse is it? –  Ali Feb 21 '14 at 0:53
    
I hope to dimensions into the millions. And very sparse... the bandwidth would be less than 16. –  Chris Conlon Feb 21 '14 at 2:39
    
OK. Are you already using a solver / custom algorithm for banded systems to compute the initial inversion of M? –  Ali Feb 21 '14 at 11:40
    
Yep yep yep yep –  Chris Conlon Feb 21 '14 at 16:42
    
OK. You would probably have better luck at scicomp.stackexchange.com Stackoverflow is a programming site. This a though question and strictly speaking not a programming question. On the other hand, at scicomp, I see similar questions more often there. In any case, good luck! –  Ali Feb 21 '14 at 17:17

1 Answer 1

If you are just interested in approximation, not the optimal solution, you can calculate the differential of the coefficients with respect to adding a sample (or more like change in mean, variance and covariance). Then you can update according to those changes.

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maybe I am wrong, but I think your suggestion is not directly implementable. I can see two ways to define the mentioned approximation: (1) F(M)=Mx-b, but when you use Taylor, you get the F(M+N), where N is the perturbation, and you want X. (2) X(M)=inv(M)B. In this case we dont have an analycal equation for inv(M) that makes possible to evaluate the derivative of inv(M) in relation to M. Am I missing something? How do you think you can get that? –  DanielTheRocketMan Feb 21 '14 at 3:13

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