5

I have the following matrices sigma and sigmad:

sigma:

    1.9958   0.7250
    0.7250   1.3167

sigmad:

    4.8889   1.1944
    1.1944   4.2361

If I try to solve the generalized eigenvalue problem in python I obtain:

    d,V = sc.linalg.eig(matrix(sigmad),matrix(sigma))

V:

    -1     -0.5614
    -0.4352    1

If I try to solve the g. e. problem in matlab I obtain:

    [V,d]=eig(sigmad,sigma)

V:

    -0.5897    -0.5278
    -0.2564    0.9400

But the d's do coincide.

11

Any (nonzero) scalar multiple of an eigenvector will also be an eigenvector; only the direction is meaningful, not the overall normalization. Different routines use different conventions -- often you'll see the magnitude set to 1, or the maximum value set to 1 or -1 -- and some routines don't even bother being internally consistent for performance reasons. Your two different results are multiples of each other:

In [227]: sc = array([[-1., -0.5614], [-0.4352,  1.    ]])

In [228]: ml = array([[-.5897, -0.5278], [-0.2564, 0.94]])

In [229]: sc/ml
Out[229]: 
array([[ 1.69577751,  1.06366048],
       [ 1.69734789,  1.06382979]])

and so they're actually the same eigenvectors. Think of the matrix as an operator which changes a vector: the eigenvectors are the special directions where a vector pointing that way won't be twisted by the matrix, and the eigenvalues are the factors measuring how much the matrix expands or contracts the vector.

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.