Unable to solve differential equation with finite difference method
1 vue (au cours des 30 derniers jours)
Afficher commentaires plus anciens
I am trying to solve a differential equation of the following form:
J = m * L^2 / 3. m and L are made-up values for someones weight and length of their leg. F_m (t) = 0. Because \phi is a small angle, sin(\phi(t)) can be rewritten as \phi(t)
I have the following code:
b = 0.02;
m = 80;
L = 0.7;
g = 9.81;
J = m * L^2/3;
a = 0; bet = 2;
alpha = 0; beta = 3/2;
N = 200;
p_function = @(t) -b / J * ones(1, N);
q_function = @(t) zeros(1, N);
r_function = @(t) (-(3 * 3 * g) / (2 * m * L^3));
% findif_ODE is the function to solve using finite difference method
[tSol, YSol] = findif_ODE([a, bet], [alpha, beta], p_function, q_function, r_function, N);
%{
Approximation of the solution of the linear limit problem
y''(x) = p(x) y'(x) + q(x) - r(x) a < x < b
y(a) = alpha y(b) = beta
with the linear finite difference scheme.
%
INPUT:
I = [a, b]: extremes of the integration interval
Ybc = [alpha, beta]: boundary conditions
p(x), q(x), r(x): known terms of the differential problem (function)
N: number of internal nodes
%
OUTPUT:
Xi(1:N+2): node vector (column vector)
Yi(1:N+2): vector of approximations (column vector)
%}
function [Xi, Yi] = findif_ODE(I, Ybc, p, q, r, N)
% Discretization step
h = (I(2)-I(1)) / (N+1);
% Node vector (row vector)
Xi = linspace(I(1),I(2),N+2);
%Tried to visualize the sizes to figure out the problem
disp(['Size of Xi ' num2str(size(Xi))])
disp(['Size of p(Xi(3:N+1)): ' num2str(size(p(Xi)))])
disp(['Size of q(Xi(2:N+1)): ' num2str(size(q(Xi)))])
disp(['Size of r(Xi(2:N+1)): ' num2str(size(r(Xi)))])
% Corfficient matrix of the linear system
A_diag = [2 + h^2 * q(Xi(2:N+1))]; % main diagonal
A_coinf = [- 1 - h * 0.5 * p(Xi(3:N+1))]; % inferior codiagonal
A_cosup = [- 1 + h * 0.5 * p(Xi(2:N))]; % superior codiagonal
%A = diag(A_diag) + diag(A_coinf,-1) + diag(A_cosup,1);
A = spdiags([A_diag', A_coinf', A_cosup'], 0:2, N, N);
% Vector of known terms (column vector)
B = h^2 * r(Xi(2:N+1));
disp(['Size of B ' num2str(size(B))])
disp(['Size of B1 ' num2str(B(1))])
disp(['Size of B1 ' num2str((1 + h * 0.5 * p(Xi(2))) * Ybc(1))])
B_1_hold = B(1);
B(1) = (1 + h * 0.5 * p(Xi(2))) * Ybc(1);
B(1) = B_1_hold;
B(N) = B(N) + (1 - h * 0.5 * p(Xi(N+1))) * Ybc(2);
B = B';
% Solution of the linear system
Yi = A \ B;
% Output
Xi = Xi';
Yi = [Ybc(1); Yi; Ybc(2)];
end
The error i get is the following:
Unable to perform assignment because the left and right
sides have a different number of elements.
Error in exercise_2_1_8>findif_ODE (line 65)
B(1) = (1 + h * 0.5 * p(Xi(2))) * Ybc(1);
Error in exercise_2_1_8 (line 19)
[tSol, YSol] = findif_ODE([a, bet], [alpha, beta], p_function, q_function, r_function, N);
I have tried to diagnose it myself, but I cannot seem to figure it out.
2 commentaires
Alan Stevens
le 18 Déc 2023
Your final boundary condition of theta = 3/2 (~ 86 degrees) is not really consistent with a small angle approximation. Since you are doing a numerical calculation there is little lost by just using sin(theta).
(This doesn't help solve your error problem I'm afraid!)
Torsten
le 18 Déc 2023
Your functions p and q always return vectors of length N and r returns a scalar. This is wrong in all the below calls to the functions:
A_coinf = [- 1 - h * 0.5 * p(Xi(3:N+1))]; % inferior codiagonal
A_cosup = [- 1 + h * 0.5 * p(Xi(2:N))]; % superior codiagonal
B = h^2 * r(Xi(2:N+1));
B(1) = (1 + h * 0.5 * p(Xi(2))) * Ybc(1);
B(N) = B(N) + (1 - h * 0.5 * p(Xi(N+1))) * Ybc(2);
Réponses (1)
Alan Stevens
le 20 Déc 2023
Should be more like this I think:
b = 0.02;
m = 80;
L = 0.7;
g = 9.81;
J = m * L^2/3;
a = 0; bet = 2;
alpha = 0; beta = 3/2;
N = 200;
p = b / J;
r = 3*g/(2*L*J);
% Approximation of the solution of the linear limit problem
% y''(x) = -p y'(x) - r*y(x) a < x < bet
% y(a) = alpha y(bet) = beta
% with the linear finite difference scheme.
% %
% INPUT:
I = [a, bet]; % extremes of the integration interval
% Ybc = [alpha, beta]: boundary conditions
% p, r: known terms of the differential problem (function)
% N: number of internal nodes
% %
% OUTPUT:
% Xi(1:N+2): node vector (column vector)
% Yi(1:N+2): vector of approximations (column vector)
% %}
% Discretization step
h = (I(2)-I(1)) / (N+1);
% Node vector (row vector)
Xi = linspace(I(1),I(2),N+2)';
% Coefficient matrix of the linear system
A_diag = diag(-(2-r*h^2)*ones(1,N+2)); % main diagonal
A_diag(1,1) = 1; A_diag(N+2,N+2) = 1;
A_coinf = diag((1-p*h/2)*ones(1,N+1),-1); % inferior codiagonal
A_cosup = diag((1+p*h/2)*ones(1,N+1),1); % superior codiagonal
A = A_diag + A_coinf + A_cosup;
A(1,2) = 0; A(N+2,N+1) = 0;
% Vector of known terms (column vector)
B = zeros(N+2,1);
B(1) = alpha; B(N+2) = beta;
% Solution of the linear system
Yi = A \ B;
% Output
plot(Xi,Yi),grid
0 commentaires
Voir également
Catégories
En savoir plus sur Special Functions dans Help Center et File Exchange
Community Treasure Hunt
Find the treasures in MATLAB Central and discover how the community can help you!
Start Hunting!