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(Before you tell me, yes, I know you should never invert the matrix. Unfortunately for my calculations, I have a matrix which I have constructed, and it must be inverted somehow.)

I have a large matrix M which is ill-conditioned. numpy.linalg.cond(M) outputs a value of magnitude e+22. The matrix M is shaped (1000,1000).

Naturally, numpy.linalg.inv() will result in many precision errors. So, I have used numpy.linalg.solve() to invert the matrix.

Consider that the matrix inverse A^{-1} is defined by A * A^{-1} = Identity. numpy.linalg.solve() computes the “exact” solution, x, of the well-determined, i.e., full rank, linear matrix equation ax = b.

So, I define the identity matrix:

import numpy as np
iddmatrix = np.identity(100)

and solve:

inverse = np.linalg.solve(M, iddmatrix)

However, because my matrix is so large and so ill-conditioned, np.linalg.solve() will not give the "exact solution". I need another method to invert the matrix.

  1. What is the standard way to implement such an inverse with SVD?
  2. How could I make this ill-conditioned matrix....well-defined?

Any recommendations are appreciated. Thanks!

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  • IIRC, if it's feasible to calculate a svd, you can easily use it to calculate a pseudo inverse. The pseudo inverse will be your inverse if your input matrix is invertible
    – cel
    Jul 6, 2015 at 17:20
  • Have you seen numpy.linalg.pinv (docs.scipy.org/doc/numpy/reference/generated/…)? Jul 6, 2015 at 19:46
  • I don't get it. Don't you have a square matrix? Why not LU decomposition?
    – Alex
    Oct 23, 2021 at 10:51

3 Answers 3

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Since SVD factorizes your matrix A as U*S*V, where S is diagonal and U, V are orthogonal, its inverse is V'*inv(S)*U', and the inverse of a diagonal matrix is just the inverse of numbers on the main diagonal.

>>> A=np.random.rand(1000,1000)
>>> u,s,v=np.linalg.svd(A)
>>> Ainv=np.dot(v.transpose(),np.dot(np.diag(s**-1),u.transpose()))
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  • Are you sure that this works? I guess you need matrix multiplication here.
    – cel
    Jul 6, 2015 at 17:33
  • 1
    np.dot is matrix multiplication. This answer performs the operation described by Jack Meagher's answer.
    – ldirer
    Jul 7, 2015 at 7:14
2

Consider what taking the SVD of a matrix actually means. It means that for some matrix M, then we can express it as M=UDV* (here let's let * represent transpose, because I don't see a good way to do that in stack overflow).

if M=UDV*:
  then: M^-1 = (UDV*)^-1 = (V*^-1)(D^-1)(U^-1)

But thanks to the fact that U's columns are the eigenvalues of MM* and V's columns are the eigenvalues of M\*M, the inverses of these matrices are their own transposes (since eigenvectors are orthogonal). So we get: M^-1 = V(D^-1)U*. Taking the inverse of a diagonal matrix is as easy as taking the multiplicative inverse of each of these elements.

Better typesetting (kind of) here: http://adrianboeing.blogspot.com/2010/05/inverting-matrix-svd-singular-value.html

1

the first argument of the dot product should be v.transpose():

import numpy as np
from numpy.linalg import inv

def svdsolve(A):
    u, s, v = np.linalg.svd(A)
    Ainv = np.dot(v.transpose(), np.dot(np.diag(s**-1), u.transpose()))
    return Ainv

temp = np.random.rand(1000, 1000)
np.allclose(svdsolve(temp), inv(temp))
>>> True

np.linalg.solve factorizes the initial matrix as A = USV, so the inverse is just V' S-1 U'

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  • this works, but wanted to hear about the execution time, it seems compared to a standard np.linalg.invert this method takes mane order more...very slow infact , so not feasible for batch proceeses
    – Ayan Mitra
    Apr 28 at 9:53

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