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I have this annoying problem and I haven't figured it out yet. I have a matrix and I want to find the eigenvectors, so I write:

val,vec = np.linalg.eig(mymatrix)

and then I got vec . My problem is when others from my group do the same with the same matrix (mymatrix) we dont get the same eigenvectors !!

Someone who can put up an explanation?

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How different are the outputs? Can you provide an example? –  JoshAdel Mar 28 '11 at 19:42
It's almost the same, but the numbers are different. –  Guest Mar 28 '11 at 19:45
could you be a bit more quantitative? Are we talking about errors near the floating point precision of your machine? Please post the outputs for a simple (small) test case that illustrates your problem. This will make it easier to help answer your question. –  JoshAdel Mar 28 '11 at 19:50
for example I get something like: array([[-4.4, 6.6, -1.7], [7.1, 7.8, -2,9], [-9.8, 2.3, -1.4]]) And they: array([[4.4, -6.6, 1.7], [7.1, 7.8, -2,9], [-9.8, 2.3, -1.4]]) So some of my result is the same, but the first in my output is multiplicated with -1 –  Guest Mar 28 '11 at 20:14
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1 Answer

The fundamental property of an eigenvector x is

A x = lambda x

for some constant lambda.

If x is an eigenvector, so is -x:

A (-x) = - A x = - lambda x = lambda (-x)

Note also that the set of eigenvectors may not be unique. For example, any vector (of the appropriate dimension) can be an eigenvector of the identity matrix.

np.linalg.eig tries to return a set of eigenvectors, but does not guarantee a particular, unique set.

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Thank you! can I do something with my code, so I can get a different output? Or do I have to live with my computer chose to calculate the eigenvectors? –  Guest Mar 28 '11 at 20:32
You have to live with what your computer chooses. –  Robert Kern Mar 28 '11 at 20:38
@Guest: If you want a unique representation of the eigenspaces of your matrix, you could compute the Grassmann coordinates of each eigenspace (but this is probably well beyond the scope of this forum). –  Sven Marnach Mar 29 '11 at 12:48
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