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I'm trying to calculate an expression of the form K = P*C.T*S^-1 (implementation of a Kalman filter)

All the involved matrices are sparse, and I would of course like to avoid calculating the actual inverse.

I tried using

import scipy.sparse.linalg as spln

self.K = self.P.dot(spln.spsolve(S.T, C).T)

The problem is that spsolve expects it's second argument to be a vector and not a matrix.

edit: Clarification, the problem could in Matlab be solved by K = P * (C / S), so what I'm looking for is a method similar to spsolve but which can accept a matrix as its second argument. This could of course be done by splitting C into a number of column vectors c1..cn and solving the problem for each of them and then reassembling them into a matrix, but I suspect doing that will be both cumbersome and inefficient.

edit2&3: The dimensions of the matrices will typically be around P~10⁶x10^6, S~100x100, C=100x10⁶. P diagonal and S symmetric and C will only have one element per row. It will be used for an implementation of a Kalman filter using sparse matrices, see

http://en.wikipedia.org/wiki/Kalman_filter#The_Kalman_filter

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Without computing the inverse, you can't compute K. What you can do without computing the inverse is computing Kx for some vector x, which would involve solving a linear system. –  Sven Marnach Oct 14 '11 at 13:18
    
I disagree, in matlab the solution to my question would simply be: K = P*(S' \ C)' or equivantly K = P*(C / S) The fact that C is a matrix instead of a vector does not change the reasoning, you do along the lines of what you are saying by solving once for each column in C. My question is about the fact that spsolve restrict me to C being a vector whereas in Matlab it can also be done for matrices. Depending on the dimension of the matrices this can still be significantly more efficient then calculating the actual inverse. –  ajn Oct 14 '11 at 14:01
    
Sorry, I implicitely assumed all matrices to be square. So why not simply iterate over the columns of C and solve for each column? Since you have to solve a linear system each time, the loop overhead wil be negligible. –  Sven Marnach Oct 14 '11 at 14:13
    
Just saw your edit. No, I don't think iterating over the colmuns of C will be inefficient. Depending on the size of the linear system, consider using an iterative solver instead of spsolve(), though. –  Sven Marnach Oct 14 '11 at 14:16
    
If there isn't any better method I will definitely try solving it by iterating over the columns, but I have a hunch it will not be so efficient. The dimensions of the matrices will typically be around P~10⁶x10^6, S~100x100, C=100x10⁶. P and S will be diagonal and C will only have one element per row. I will update my question with this information aswell. –  ajn Oct 14 '11 at 14:32

1 Answer 1

up vote 1 down vote accepted

As a workaround can do

import numpy as np
from scipy.sparse.linalg import splu

def spsolve2(a, b):
    a_lu = splu(a)
    out = np.empty((A.shape[1], b.shape[1]))
    for j in xrange(b.shape[1]):
        out[:,j] = a_lu.solve(b[:,j])
    return out

self.K = self.P.dot(spsolve2(S.T, C).T)

But yes, it's a bug that spsolve does not accept matrices.

However, as your S is not very large, you can as well use a dense inverse.

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