[V,D]=eig(S1,S2) ?

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Samhitha Vadlamani il 12 Ott 2016

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Commentato: yabes dwi nugroho il 2 Dic 2016

question reframed : I am performing CSP and while simultaneous diagonalization of two classes , I came across the syntax [V,D]=eig(S1,S2) , where , S1 = PAP' and S2= PBP' ( A and B - covariance matrices of class1 and 2 respectively and P being a whitening matrix obtained from the composite covariance of classes 1 and 2 ) . Now , the algorithm claims the following conditions for eigenvalue decompositions of S1 and S2 simultaneously: S1=V(lambda_1)V' ; S2=V(lambda_2)V' ; lambda_1+lambda_2=I , where V is the common eigenvector for S1 and S2 . In the code for CSP, there was a line that says [V,e]=eig(S1,S2) [ which I'm thinking to be the simultaneous diagonalization of S1 and S2 ] . How are the conditions captured in the formula above and how can I access lambda_1 and lambda_2 separately to check if the final condition has been satisfied ? Thank you.

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Massimo Zanetti il 12 Ott 2016

Modificato: Massimo Zanetti il 12 Ott 2016

[V,e]=eig(S1,S2) is not "simultaneous diagonalization" of S1,S1 in the sense that they have the same eigenvectors. They DO NOT have the same eigenvectors. It is called "simoultaneous diagonalization" because it gives the right-eigenvectors of both A and (after a simple manipulation) the ones of B.

In fact, V is the matrix of right-eigenvectors of A, and (D^-1*A)*V is the set of right-eigenvectors of B.

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Answer 1

Massimo Zanetti il 12 Ott 2016

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Modificato: Massimo Zanetti il 12 Ott 2016

Apri in MATLAB Online

They are not captured by the syntax of eig(A,B). Let me explain you why:

The call

[V,D] = eig(A,B)

returns diagonal matrix D of generalized eigenvalues and full matrix V whose columns are the corresponding right eigenvectors of A, so that A*V = B*V*D.

Now, from this you easily get the right eigenvectors of B (that are not the same to that of A) B*V=D^-1*A*V. Assume that there exists a common eigenvector w for A and B, then Aw=Bw=h. Applying the equivalence above you get Bw*D = D^-1*Aw, and thus DhD=h. This is true only if D is the identity matrix.