I understand that you're implementing the power method in MATLAB to find the dominant eigenvalue and eigenvector of a matrix. And wish to modify the matrix for subsequent iterations to find more eigenvalues and eigenvectors.
You can modify the matrix by subtracting the outer product of the found eigenvector, scaled by the found eigenvalue, from the original matrix. This is known as deflation.
Here's how you can adjust your code to include this step:
clc;
% Assignment Conditions
FA = @(k_1, k_2, k_3, m_1, m_2) [-(k_2+k_1)/m_1 , k_2/m_1; k_2/m_2, -(k_3+k_2)/m_2];
A = FA(1, 1, 1, 2, 1);
% Stopping Criteria
e_s = 0.00005;
disp(['<strong> Stopping Criteria: </strong>', num2str(e_s), '%'])
% Vector for Eigenvalues
Eigenvalue_summary = zeros(1, height(A));
% Dominant Eigenvalue
V_approximation = ones(height(A), 1, 'double'); % Initial guess
Iteration = 0;
while true
Iteration = Iteration + 1;
disp(['<strong>Iteration: </strong>', num2str(Iteration)])
Eigenvalue = norm(A*V_approximation);
Eigenvector = (A*V_approximation) / Eigenvalue;
% Update for next iteration
V_approximation = Eigenvector;
% Check convergence
if Iteration > 1 && abs(Eigenvalue - Eigenvalue_summary(Iteration-1)) < e_s
break;
end
Eigenvalue_summary(Iteration) = Eigenvalue;
% Modify A for next eigenvalue (Deflation)
A = A - Eigenvalue * (Eigenvector * Eigenvector');
end
% Final Results
Dominant_Eigenvector = Eigenvector;
Dominant_Eigenvalue = Eigenvalue;
disp(['Dominant Eigenvalue: ', num2str(Dominant_Eigenvalue)]);
disp('Dominant Eigenvector: ');
disp(Dominant_Eigenvector);
This code iteratively finds the dominant eigenvalue and eigenvector, then deflates the matrix `A` for subsequent iterations.
Refer to the following MathWorks Documentation for more details:
Thanks
Chetan
