eig return complex values

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Michael cohen on 22 Jan 2022

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Commented: Matt J on 23 Jan 2022

Hello,

I'm trying to find the eigenvalues and eigenvectors of an invertible matrix. The eig function returns me complex values.

But the matrix is invertible: I invert it on Pascal.

How to explain and especially how to solve this problem please?

The matrix I am trying to invert is the inv(C)*A matrix, from the attached files.

Thanks,

Michael

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Michael cohen on 22 Jan 2022

Edited: Michael cohen on 22 Jan 2022

Thank you, but in fact it is the matrix_invC.A.mat that I try to diagonalize :)

Matt J on 22 Jan 2022

Edited: Matt J on 22 Jan 2022

That matrix is not symmetric, so there is no reason to think it will have real eigenvalues.

Accepted Answer

Torsten on 22 Jan 2022

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Edited: Torsten on 22 Jan 2022

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Use

E = eig(A,C)

instead of

E = eig(inv(C)*A)

E = eig(C\A)

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Torsten on 22 Jan 2022

Edited: Torsten on 22 Jan 2022

@Matt J

Although negligible, eig(A,C) produces no imaginary parts.

@Michael cohen

E = eig(A,C) solves for the lambda-values that satisfy

A*x = lambda*C*x (*)

for a vector x~=0.

If C is invertible, these are the eigenvalues of inv(C)*A (as you can see by multiplying (*) with

inv(C) ).

Michael cohen on 23 Jan 2022

Wouah, thank you very much. It’s very clear and allow us to solve our problem 🙏

More Answers (1)

Matt J on 22 Jan 2022

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Edited: Matt J on 22 Jan 2022

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matrices.mat

It turns out that B=C\A does have real eigenvalues in this particular case, but floating point errors approximations produce a small imaginary part that can be ignored.

load matrices
E=eig(C\A);
I=norm(imag(E))/norm(real(E))
I = 3.3264e-18

So just discard the imaginary values,

E=real(E);

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Michael cohen on 23 Jan 2022

Thank you very much @Matt J for all those explanations !

Matt J on 23 Jan 2022

You 're welcome but please Accept-click one of the answers.

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