# scipy generalized eigenproblem with positive semidefinite

Hi, guys!!!

I want to compute generalized eigendecomposition of the form:

Lf = lambda Af

by using scipy.sparse.linalg.eigs function, but get this error:

/usr/local/lib/python2.7/dist-packages/scipy/linalg/decomp_lu.py:61: RuntimeWarning: Diagonal number 65 is exactly zero. Singular matrix. RuntimeWarning) ** On entry to DLASCL parameter number 4 had an illegal value

I am passing three arguments, a diagonal matrix, a positive semi-definite (PSD) matrix and numeric value K (first K eigenvalues). Matlab's eigs function performs well using the same input parameters, but in SciPy as I have understood, in order to compute with PSD I need to specify sigma parameter as well.

So, my question is: is there a way to avoid setting sigma parameter, as it is in MatLab, or if not, how to pick up sigma value?

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The error appears to mean that in your generalized eigenproblem

``````L x = lambda A x
``````

the matrix A is not positive definite (check the eigs docstring -- in your case the matrix is probably singular). This is a requirement for ARPACK mode 2. However, you can try specifying `sigma=0` to switch to ARPACK mode 3 (but note that the meaning of the `which` parameter is inverted in this case!).

Now, I'm not sure what Matlab does, but a possibility is that it's calculating the pseudoinverse rather than the inverse of `A`. To emulate this, do

``````from scipy.sparse.linalg import LinearOperator
from scipy.linalg import lstsq

Ainv = LinearOperator(matvec=lambda x: lstsq(A, x)[0], shape=A.shape)
w, v = eigs(L, M=A, Minv=Ainv)
``````

Check the results --- I don't know what will happen in this case.

Alternatively, you may try to specify a nonzero `sigma`. What you should select depends on the matrices involved. It affects the eigenvalues that are picked --- for instance with `which='LM'` are those for which `lambda' = 1/(lambda - sigma)` is large. Otherwise, it can probably be chosen arbitrarily, of course it's probably better for the Krylov progress if the transformed eigenvalues `lambda'` which you are interested in become well separated from the other eigenvalues.

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