error is not showing but plot is not generating
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clear
%% %% current density equation J=dv/dx=0 at x=0 boundary condition
%% u=y(1)
%% v=y(2)
%% du/dx=dy(1)/dx=y(3)
%%d^2u/dx^2=dy(3)/dx=gamma*y(1)/(1+alpha*y(1)
%% dv/dx=dy(2)/dx=y(4)
%% d^2v/dx^2=dy(4)/dx=a*delta_v*y(4)-(2/epsilon)*gamma*y(1)/(1+alpha*y(1)
alpha = 0.1;
gamma = [1, 50, 100, 500, 1000];
epsilon = 1;
a = 1000;
fcn = @(x, y) [y(3); y(4); (gamma * y(1)) / (1 + alpha * y(1)); a * v * y(4) - (2 / epsilon) * (gamma * y(1)) / (1 + alpha * y(1))];
bc = @(ya, yb) [ya(1)-1; ya(2); yb(3); 0]; %% J=dv/dx=0 at x=0 so yb(4) is 0
guess = @(x) [1; 0; 0; 0]; %% at x=0, u=1, v=0, du/dx=0, dv/dx=0
xmesh = linspace(0, 1, 100);
solinit = bvpinit(xmesh, guess);
for i = 1:numel(gamma)
sol = bvp4c(fcn, bc, solinit);
y_plot = deval(sol, xmesh);
v = y_plot(1, :);
dv_dx = y_plot(2, :);
J = dv_dx;
delta_v_star = v;
% Plot delta_v_star versus J
figure;
plot(delta_v_star, J);
xlabel(' delta_v_star');
ylabel('J');
title('Plot of delta_v_star verses current density (J)');
legend('\gamma = 1', '\gamma = 50', '\gamma = 100', '\gamma = 500', '\gamma = 1000');
xlim([1e-4, 1e2]);
ylim([0, 70]);
end
i defined all the parameters but plot is not generating any mistakes in the code
0 Kommentare
Antworten (1)
Walter Roberson
am 2 Dez. 2023
Bearbeitet: Walter Roberson
am 4 Dez. 2023
The Jacobian is singular if y(4) = dv/dx = 0, which it is because of your boundary conditions.
That said, even if I change the boundary conditions, I still get told singular jacobian.
clear
%% %% current density equation J=dv/dx=0 at x=0 boundary condition
%% u=y(1)
%% v=y(2)
%% du/dx=dy(1)/dx=y(3)
%%d^2u/dx^2=dy(3)/dx=gamma*y(1)/(1+alpha*y(1)
%% dv/dx=dy(2)/dx=y(4)
%% d^2v/dx^2=dy(4)/dx=a*delta_v*y(4)-(2/epsilon)*gamma*y(1)/(1+alpha*y(1)
alpha = 0.1;
gamma = [1, 50, 100, 500, 1000];
epsilon = 1;
a = 1000;
bc = @(ya, yb) [ya(1)-1; ya(2); yb(3); 0]; %% J=dv/dx=0 at x=0 so yb(4) is 0
guess = @(x) [1; 0; 0; 0]; %% at x=0, u=1, v=0, du/dx=0, dv/dx=0
xmesh = linspace(0, 1, 100);
solinit = bvpinit(xmesh, guess);
syms X Y [1 4]
for i = 1:numel(gamma)
fcn = @(x, y) [y(3); y(4); (gamma(i) * y(1)) / (1 + alpha * y(1)); a * y(2) * y(4) - (2 / epsilon) * (gamma(i) * y(1)) / (1 + alpha * y(1))];
i
F = fcn(X, Y)
Jac = jacobian(F)
rank(Jac)
detJac = det(Jac)
[N,D] = numden(detJac)
solve(N)
solve(D)
sol = bvp4c(fcn, bc, solinit);
y_plot = deval(sol, xmesh);
v = y_plot(1, :);
dv_dx = y_plot(2, :);
J = dv_dx;
delta_v_star = v;
% Plot delta_v_star versus J
figure;
plot(delta_v_star, J);
xlabel(' delta_v_star');
ylabel('J');
title('Plot of delta_v_star verses current density (J)');
legend('\gamma = 1', '\gamma = 50', '\gamma = 100', '\gamma = 500', '\gamma = 1000');
xlim([1e-4, 1e2]);
ylim([0, 70]);
end
4 Kommentare
Walter Roberson
am 4 Dez. 2023
bc = @(ya, yb) [ya(1)-1; ya(2); yb(3); 0]; %% J=dv/dx=0 at x=0 so yb(4) is 0
That has a fixed element of 0, and expects to work with vectors of length 4. The result can be at most rank 3, so the jacobian of those boundary conditions must be singular.
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