# Generalized eigenvalue problem

I'm trying to convert a generalized eigenvalue problem into a normal eigenvalue calculation.

I have this code:

`[V,D,flag] = eigs(A, T);`

Now I convert it into:

``````A1 = inv(T)*A;
[V1,D1,flag1] = eigs(A1);
``````

Shouldn't I get the same result? From what I understand in the Matlab documentation, the first equation solves:

``````A*V = B*V*D
``````

and the second one solves:

``````A*V = V*D
``````

am I missing something?

Thanks!!

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Is `T` invertible? –  Jacob Jul 19 '11 at 13:36
Yes, it is a diagonal matrix –  Sara Jul 19 '11 at 13:56

A quick example:

``````A = rand(4); B = randn(4); B = B'*B;         %'# some matrices
[VV,DD] = eig(B\A);
[V,D] = eigs(A,B);
V = bsxfun(@rdivide, V, sqrt(sum(V.*V)));    %# make: norm(V(:,i))==1
``````

The result:

``````V =
-0.64581       0.8378      0.77771      0.50851
0.70571     -0.51601     -0.32503     -0.70623
0.27278     0.076874     -0.51777      0.25359
0.10245      0.16095     -0.14641     -0.42232
VV =
-0.64581       0.8378     -0.77771     -0.50851
0.70571     -0.51601      0.32503      0.70623
0.27278     0.076874      0.51777     -0.25359
0.10245      0.16095      0.14641      0.42232
D =
17.088            0            0            0
0      0.27955            0            0
0            0     -0.16734            0
0            0            0     0.027889
DD =
17.088            0            0            0
0      0.27955            0            0
0            0     -0.16734            0
0            0            0     0.027889
``````

Note: The eigenvalues are not always sorted the same, also the sign convention might be different...

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First check if `T` is invertible. Second, I'm sure `D = D1` and that `V = V1` up to a scale factor. Check if each column of `V1` is the same as the corresponding column of `V` up to a scale factor (i.e. look at `V./V1`).