I am looking to solve a problem of the type: Aw = xBw
where x
is a scalar (eigenvalue), w
is an eigenvector, and A
and B
are symmetric, square numpy matrices of equal dimension. I should be able to find d
x/w pairs if A
and B
are d x d
. How would I solve this in numpy? I was looking in the Scipy docs and not finding anything like what I wanted.

Check out stackoverflow.com/questions/12672408/…– emethJul 15 '14 at 7:52

That is exactly what I want to do, but in python.– Andrew LathamJul 15 '14 at 7:55
For real symmetric or complex Hermitian dense matrices, you can use scipy.linalg.eigh()
to solve a generalized eigenvalue problem. To avoid extracting all the eigenvalues you can specify only the desired ones by using subset_by_index
:
from scipy.linalg import eigh
eigvals, eigvecs = eigh(A, B, eigvals_only=False, subset_by_index=[0, 1, 2])
One could use eigvals_only=True
to obtain only the eigenvalues.

Thanks for clearing this up! That example in the docs for this function was pretty unclear at first glance. Jul 16 '14 at 2:54

This is reassuring for my purposes, @Saullo, but I'm having problems. By my reckoning, eigh is a specialisation of eig. However, if I use eigh and eig with the same inputs I get completely different answers. Is there an additional distinction? Jun 30 '20 at 16:25


@SaulloG.P.Castro, I am  I was checking them in my test case that they were both symmetric and positive definite. I've sidestepped the problem now, but could it be that eig and eigh don necessarily return the results in the same order? Jul 3 '20 at 10:27
Have you seen scipy.linalg.eig
? From the documentation:
Solve an ordinary or generalized eigenvalue problem of a square matrix.
This method have optional parameter b
:
scipy.linalg.eig(a, b=None, ...
b : (M, M) array_like, optional Righthand side matrix in a generalized eigenvalue problem. Default is None, identity matrix is assumed.


3so, what's the problem?
scipy.linalg.eig(a, b=None,...
: parameter b: Righthand side matrix in a generalized eigenvalue problem. Default is None, identity matrix is assumed. Jul 15 '14 at 7:56