np.linalg.solve solves for x in a problem of the form Ax = b.

For my application, this is done to avoid calculating the inverse explicitly (i.e inverse(A)b = x)

I'd like to access what the effective inverse is that was used to solve this problem but looking at the documentation it doesn't appear to be an option... Is there a reasonable alternative approach I can follow to recover the inverse of A?

(np.linalg.inv(A) is not accurate enough for my use case)

  • Why do you think numpy.linalg.solve would be any better at calculating inverses than numpy.linalg.inv? Jun 13 at 6:06
  • because it actually recovers a more accurate result. I get different parameters when I do it both ways. Not tremendously different but different enough to matte for what I'm doing And I know they're more accurate because of the math theory behind what answer I should recover... Hopefully that makes sense Jun 13 at 6:12
  • Also I think there's some docs that talk about it. I read it on a discussion board. I implemented GLM first and then realized that np.linalg.solve would go faster and should recover the same result. GLM and np.linalg.solve both recover the right answer but inverse doesn't Jun 13 at 6:15
  • numpy.linalg.solve is better at its own job than numpy.linalg.inv. It is not better at numpy.linalg.inv's job than numpy.linalg.inv. Jun 13 at 6:18
  • 1
    It's not obvious from inv code, but often the inverse is calculated with solve(A, eye(...)).
    – hpaulj
    Jun 13 at 16:24

Following the docs and source code, it seems NumPy is calling LAPACK's _gesv to compute the solution, the documentation of which reads:

The routine solves for X the system of linear equations A*X = B, where A is an n-by-n matrix, the columns of matrix B are individual right-hand sides, and the columns of X are the corresponding solutions.

The LU decomposition with partial pivoting and row interchanges is used to factor A as A = P * L * U, where P is a permutation matrix, L is unit lower triangular, and U is upper triangular. The factored form of A is then used to solve the system of equations A * X = B.

The NumPy implementation for solve doesn't return the inverted matrix back to the caller, and just frees the memory for the inverted matrix, so there's no hope there. SciPy provides low-level access to LAPACK so you should be able to access the result from there. You can follow the actual implementation in LAPACK's Fortran source code dgesv.f, dgetrf.f and dgetrs.f. Alternatively, you could note that NumPy's inv still calls the same underlying code, so it might be enough for your use case... You didn't specify why is it that you need the approximate inverse matrix.

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