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I have an NxN symmetric and tridiagonal matrix computed by a Python code and I want to diagonalize it.

In the specific case I'm dealing with N = 6000, but the matrix can become larger. Since it is sparse, I assumed the best way to diagonalize it was to use the algorithm scipy.sparse.linalg.eigsh(), which performed extremely good with other sparse and symmetric matrices (not tridiagonal ones, though) I worked with. In particular, since I need only the low lying part of the spectrum, I'm specifying k=2 and which='SM' in the function.

However, in this case this algorithm seems not to work, since after approximately 20 minutes of computation I get the following error:

ArpackNoConvergence: ARPACK error -1: No convergence (60001 iterations, 0/2 eigenvectors converged)

Why is this happening? Is it a problem related to some properties of tridiagonal matrices? Which Python (and please, only Python!) routine can I use in order to diagonalize my matrix in an efficient way?

Here's the requested minimal code to reproduce my error:

import scipy.sparse.linalg as sl
import numpy as np

dim = 6000
a = np.empty( dim - 1 )
a.fill( 1. )
diag_up = np.diag( a, 1 )
diag_bot = np.diag( a, -1 )

b = np.empty( dim )
b.fill( 1. )

mat = np.diag( b ) + diag_up + diag_bot
v, w = sl.eigsh(mat, 2, which = 'SM')

On my pc the construction of the matrix takes 364ms, while the diagonalization gives the reported error.

  • 1
    Could you provide a minimal working example? Could there be a problem with casting? scipy.sparse functions work with sparse arrays, which have a different representation in memory and maybe what you are observing is related to this? Have you tried profiling your code? – norok2 Sep 21 '17 at 13:39
  • You may find this very useful. O(nlogn) rocks – Marco Sep 21 '17 at 13:40
  • @norok2 done, thanks for answering. – Simone Bolognini Sep 21 '17 at 13:52
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    I'd stick with scipy.linalg.eigh() if that works for you. Not sure why the function does not converge in this case. – norok2 Sep 21 '17 at 15:00
  • @norok sorry for the late answer. scipy.linalg.eigh() is fast enough for me, thanks. – Simone Bolognini Oct 23 '17 at 9:40
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ARPACK is good at finding the large-magnitude eigenvalues but can struggle to find the small ones. Fortunately, you can work around this quite easily by using the shift-invert options built into eigsh. See, for example, here.

import scipy.sparse.linalg as sl
import scipy.sparse as spr
import numpy as np

dim = 6000
diag = np.empty( dim )
diag.fill( 1. )

# construct the matrix in sparse format and cast to CSC which is preferred by the shift-invert algorithm
M = spr.dia_matrix((np.array([diag, diag, diag]), [0,-1, 1]), shape=(dim,dim)).tocsc()

# Set sigma=0 to find eigenvalues closest to zero, i.e. those with smallest magnitude. 
# Note: under shift-invert the small magnitued eigenvalues in the original problem become the large magnitue eigenvalue
# so 'which' parameter needs to be 'LM'
v, w = sl.eigsh(M, 2, sigma=0, which='LM')
print(v)

For this particular example problem, you can verify that the above is finding the correct eigenvalues since the eigenvalues happen to have an explicit formula:

from math import sqrt, cos, pi
eigs = [abs(1-2*cos(i*pi/(1+dim))) for i in range(1, dim+1)]
print(sorted(eigs)[0:2])

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