# Python eig for generalized eigenvalue does not return correct eigenvectors

Trying to use scipy's linalg.eig to solve a generalized eigenvalue problem. I then check the solution I get and it does not seem like proper eigenvectors were returned. Also, the documentation suggests vectors returned are normalized and this is not the case (though that doesn't bother me that much).

Here are sample matrices:

``````>>> a
array([[  2.05630374e-01,   8.89584493e-10,  -1.46171715e-06],
[  8.89584493e-10,   2.38374743e-02,   9.43440334e-06],
[ -1.46171715e-06,   9.43440334e-06,   1.39685787e-02]])
>>> b
array([[ 0.22501692, -0.07509864, -0.05774453],
[-0.07509864,  0.02569336,  0.01976284],
[-0.05774453,  0.01976284,  0.01524993]])
``````

Running eig I get:

``````>>> w,v = linalg.eig(a,b)
>>> w
array([  3.08431414e-01+0.j,   5.31170281e+01+0.j,   6.06298605e+02+0.j])
>>> v
array([[-0.26014092, -0.46277857, -0.0224057 ],
[ 0.76112351, -0.59384527, -0.83594841],
[ 1.        , -1.        ,  1.        ]])
``````

And then testing the result:

``````>>> a*v[:,0]
array([[ -5.34928750e-02,   6.77083674e-10,  -1.46171715e-06],
[ -2.31417329e-10,   1.81432622e-02,   9.43440334e-06],
[  3.80252446e-07,   7.18074620e-06,   1.39685787e-02]])
>>> w[0]*b*v[:,0]
array([[-0.01805437+0.j, -0.01762974+0.j, -0.01781023+0.j],
[ 0.00602559-0.j,  0.00603163+0.j,  0.00609548+0.j],
[ 0.00463317-0.j,  0.00463941+0.j,  0.00470356+0.j]])
``````

I thought those two will be equal but they are not... I also tried using eigh instead with no success. Would appreciate any help, I'm obviously missing something.

-
What version of scipy are you using ? I am surprised as eig is supposed to return 3 arrays ! –  Nicolas Barbey Aug 2 '12 at 14:40
Using 0.10.1. If I understand correctly, by default only the right eigenvectors are returned, see: docs.scipy.org/doc/scipy/reference/generated/… and therefore only two arrays are returned –  nickb Aug 2 '12 at 14:49

You can see what's going on by looking at the shape of your output. Your `a*v[:,0]` should give a vector, so why are you getting a 3x3 array? Answer: because you're not doing matrix multiplication, you're doing component-wise array multiplication.

IOW, you did

``````>>> a * v[:,0]
array([[ -5.34928759e-02,   6.77083679e-10,  -1.46171715e-06],
[ -2.31417334e-10,   1.81432623e-02,   9.43440334e-06],
[  3.80252453e-07,   7.18074626e-06,   1.39685787e-02]])
>>> w[0] * b * v[:,0]
array([[-0.01805437+0.j, -0.01762974+0.j, -0.01781023+0.j],
[ 0.00602559-0.j,  0.00603163+0.j,  0.00609548+0.j],
[ 0.00463317-0.j,  0.00463941+0.j,  0.00470356+0.j]])
``````

when you really wanted

``````>>> a.dot(v[:,0])
array([-0.05349434,  0.0181527 ,  0.01397614])
>>> w[0] * b.dot(v[:,0])
array([-0.05349434+0.j,  0.01815270+0.j,  0.01397614+0.j])
``````

or

``````>>> matrix(a)*matrix(v[:,0]).T
matrix([[-0.05349434],
[ 0.0181527 ],
[ 0.01397614]])
>>> w[0]*matrix(b)*matrix(v[:,0]).T
matrix([[-0.05349434+0.j],
[ 0.01815270+0.j],
[ 0.01397614+0.j]])
``````
-
Thanks! any idea why the eigenvectors are not normalized? –  nickb Aug 2 '12 at 16:03
It looks to me like they are normalized: the maximum absolute value of each vector is 1. That might not have been the normalization you were expecting, but it is a normalization.. :^) –  DSM Aug 2 '12 at 16:14
The normalization comes directly from LAPACK: netlib.org/lapack/double/dggev.f –  pv. Aug 3 '12 at 9:09