Equivalent Impedance using Matrix, Eigen value and Eigen vector, norm
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I am solving this below problem(attachment 1). How to find the exp(theta1) and exp(theta2)...?
- Attachment pdf.pdf is the problem I am trying to solve.
- Attachment Tzeng_2006_J._Phys._A__Math._Gen._39_8579.pdf is the theory
Y11 =1-1i/sqrt(3); Y12 =1i/sqrt(3); Y13 =-1;
Y21 =1i/sqrt(3); Y22 =0; Y23 =-1i/sqrt(3);
Y31 =-1; Y32 =-1i/sqrt(3); Y33 =1+1i/sqrt(3);
Y11 = Y12 + Y13 ; Y22 = Y21 + Y23 ; Y33 = Y31 + Y32 ;
L = [Y11, Y12, Y13; Y21, Y22, Y23; Y31, Y32, Y33];
[EVector,EValue] = eig(L'*L) ; % V = Values % D = VECTORS
Sigma_2 = sqrt(EValue(2,2))
Sigma_3 = sqrt(EValue(3,3))
3 Comments
John D'Errico
on 8 Nov 2023
You already know how to use eig. It returns all of the eigenvalues, and their associated eigenvectors.
Throw away all of the eigenvalues that are negative, as well as the eigenvectors associated with the ones you don't want. Toss any that are complex too, if that is a problem. What remains are the non-negative eigenvalues, as well as their eigenvectors.
So where is the problem?
RAJA KUMAR
on 9 Nov 2023
Q = @(v) sym(v);
Y11 = 1-1i/sqrt(Q(3)); Y12 = 1i/sqrt(Q(3)); Y13 = Q(-1);
Y21 = 1i/sqrt(Q(3)); Y22 = Q(0); Y23 = -1i/sqrt(Q(3));
Y31 = -1; Y32 = -1i/sqrt(Q(3)); Y33 = 1+1i/sqrt(Q(3));
Y = [Y11, Y12, Y13; Y21, Y22, Y23; Y31, Y32, Y33; Y41, Y42, Y43]
A = L'*L ; % e = eig(L_P*L);
[V,EVC] = eig(A) % V = Values % D = VECTOR
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