How to find eigenvalues for a system of lenearized ordinary differential equations?

13 vues (au cours des 30 derniers jours)
Tanya Sharma
Tanya Sharma le 5 Oct 2019
Commenté : Poly le 10 Mar 2022
I have a system of linearized ODEs with corresponding boundary conditions.
%----------------------------system of ODEs--------------------------------------%
y'(1)=y(2)
y'(2)=y(3)
y'(3)=(phi./Da).*y(2)+(2.*phi.*Fr./A1).*fd.*y(2)-(fd1.*1./A1).*y(3)-(fdd.*1./A1).*y(1)+(2.*fd.*1./A1).*y(2)-(e./A1).*y(2)-(phi.*Ra./(A1^2).*A2).*y(4)
y'(4)=y(5)
y'(5)=-(Pr./A2).*(fd.*y(5)+thd.*y(1)+e.*y(4))];
%---------------------------boundary conditions----------------------------------%
y(1)=y(2)=y(4)=0 at eta=0
y(2)=y(4)=0 at eta=0;
here Pr phi Ra Da Fr A1 A2 fd1 fd fdd thd are known quantities and 'e' is unknown.
I need to solve the system to find out the eigenvalues (e).
Thanks in advance.

Connectez-vous pour répondre à cette question.

Réponse acceptée

Pavel Osipov
Pavel Osipov le 5 Oct 2019
Tanya, hi.
write so:
dyi/dt =...y1 (t)+...y2 (t)+...+y5(t);
let x (t)=[y1;y2;...;y5]; ->
((V/ve) x=Ah; A - matrix coeff. Your system. Let's formally denote d/dt=p
px-Ax=0; - > (p*E-A) x=0; since x is not 0, then
det(p*E-A)=0. This is the equation for the eigenvalues of p.
  2 commentaires
Tanya Sharma
Tanya Sharma le 9 Oct 2019
The unkown 'e' is already in the equations y'(3) and y'(4). I want to find all the possible eigenvalues 'e' for this problem. Can you explain again?
Thanks in advance.
Poly
Poly le 10 Mar 2022
Hello Tanya!! I don't know whether you get the code right or not? but can you share the code if possible

Connectez-vous pour commenter.

Plus de réponses (2)

Pavel Osipov
Pavel Osipov le 9 Oct 2019
Hi!
det(p*E-A)=0. This is the equation for the eigenvalues of p. - -> The unkown "p" is solution det(p*E-A)=0. det - is the determinant with dimensions 5x5.
px-Ax=0 ->Ax=px, p is eigenvalues of A MATLAB command [V,D] = eig(A) returns diagonal matrix D of eigenvalues and matrix V whose columns are the corresponding right eigenvectors, so that A*V = V*D. (from MATLAB help).
eigenvalues p is 5x1 vector = liagonal elements D. eigenvectors of A see at columns V.
  1 commentaire
Tanya Sharma
Tanya Sharma le 21 Oct 2019
Thanks Pavel!
But this will give me only five eigenvalues. As I am solving the eigenvalue of a differential equation and it can have many eigenvalues.
I am attaching the linearized eigenvalue problem. Is there a way I can find the unknown eigenvalues?

Connectez-vous pour commenter.

Pavel Osipov
Pavel Osipov le 24 Nov 2019
Answ1.JPG
Answ2.JPG
See attachment

Catégories

En savoir plus sur Linear Algebra dans Help Center et File Exchange

Tags

Community Treasure Hunt

Find the treasures in MATLAB Central and discover how the community can help you!

Start Hunting!

Translated by