# sparse matrix multiplication involving inverted matrix

I have two large square sparse matrices, A & B, and need to compute the following: `A * B^-1` in the most efficient way. I have a feeling that the answer involves using `scipy.sparse`, but can't for the life of me figure it out.

After extensive searching, I have run across the following thread: Efficient numpy / lapack routine for product of inverse and sparse matrix? but can't figure out what the most efficient way would be.

Someone suggested using LU decomposition which is built into the sparse module of scipy, but when I try and do LU on sample matrix is says the result is singular (although when I just do a * B^-1 i get an answer). I have also heard someone suggest using `linalg.spsolve()`, but i can't figure out how to implement this as it requires a vector as the second argument.

If it helps, once I have the solution s.t. `A * B^-1 = C`, i only need to know the value for one row of the matrix C. The matrices will be roughly 1000x1000 to 1500x1500.

-
How large are these matrices? –  irrelephant Aug 2 '12 at 4:06

Actually 1000x1000 matrices are not that large. You can compute the inverse of such a matrix using numpy.linalg.inv(B) in less than 1 second on a modern desktop computer.

But you can be much more efficient if you rewrite your problem taking into account the fact that you only need one row of C (this is actually very often the case).

Let us write d_i = [0 0 0 ... 0 1 0 ... 0 ], a vector with only one one on the i-th element. You can write, if ^t denotes the transpose :

``````AB^-1 = C <=> A = CB <=> A^t = B^t C^t
``````

For the i-th row :

``````A^t d_i = B^t C^t d_i <=> a_i = B^t c_i
``````

So you have a linear inverse problem which can be solved using numpy.linalg.solve

``````ci = np.linalg.solve(B.T, a[i])
``````
-
Thank you! I will try this and let you know how it goes. Also, I understand that it wouldn't take long to do the inversion, but I will have to do this process tens of thousands of times so I want to fine tune it as much as possible :) –  user1554752 Aug 2 '12 at 14:22
I tried it out and after quite a bit of scratching my head i got it to work. Your solution works when using `numpy.linalg.solve()`, but I get an incorrect answer when using `sparse.linalg.spsolve`. My arrays where the following: `B.T = [[0.802, -0.396, 0.], [-0.594, 0.604, 0.], [-0.198, -0.198, 0.01]]` and `A.T: [[.25,.5,0.],[.75,.5,0.],[.0,.0,1.]]`; The correct answer for the 2nd row is `[2.00654938, 2.80114293, 95.19230769]`, but spsolve spits out `[.5, .5, .0]` –  user1554752 Aug 2 '12 at 21:46
Ok. I assumed that spsolve worked the same as solve which is apparently not the case. But actually I am not so sure that from where you are now, using sparse matrices will gain you any speed-up. The main advantage would be memory consumption, but you are probably not limited by this, right ? –  Nicolas Barbey Aug 3 '12 at 8:39
I will have to wait until later on in the implementation to determine if there is a speed up (and if it was memory bound). I finally ran across someone with a similar problem. It looks like spsolve has problems in a 64 bit windows environment (when using EPD+MKL), and just returns the second argument passed to it. But I tested it on the Ubuntu version of EPD and it worked fine. –  user1554752 Aug 3 '12 at 15:45