Can anybody help me to code boundary conditions in MATLAB for Keller Box Method?
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Can anybody help me to code boundary conditions in MATLAB for Keller Box Method?
f^'=1,f=S,θ^'=-r_1 [1+θ],ϕ^'=-r_2 [1+ϕ] at η=0
f^'=0,f^''=0,θ=0,ϕ=0 as η→∞
1 Comment
vijayakumar
on 30 Oct 2024
how to set MATLAB code for velocity slip and temperature slip boundary condition for kelller box method please help me out
at eta=0, f(eta)=0, f^'(eta)=SF*f^''(eta), theta=1+ST*theta^'(eta)
at eta=infinite, f^'=0, theta=0
Answers (2)
% Define parameters
r_1 = 0.1;
r_2 = 0.2;
S = 2.0;
% Define the differential equations
% y(1) = f, y(2) = f', y(3) = θ, y(4) = ϕ
ode_system = @(eta, y) [y(2); 1; y(3); y(4)];
% Define the boundary conditions at η = 0
initial_conditions = [S, 1, 0, 0];
% Define the boundary conditions at η → ∞
eta_infinity = 100; % Choose a large value
final_conditions = [0, 0, 0, 0];
% Solve the differential equations
[eta, result] = ode45(ode_system, [0, eta_infinity], initial_conditions);
% Extract the solutions
f = result(:, 1);
f_prime = result(:, 2);
theta = result(:, 3);
phi = result(:, 4);
% Plot the solutions
subplot(2, 2, 1);
plot(eta, f);
xlabel('η');
ylabel('f');
title('f vs. η');
subplot(2, 2, 2);
plot(eta, f_prime);
xlabel('η');
ylabel("f'");
title("f' vs. η");
subplot(2, 2, 3);
plot(eta, theta);
xlabel('η');
ylabel('θ');
title('θ vs. η');
subplot(2, 2, 4);
plot(eta, phi);
xlabel('η');
ylabel('ϕ');
title('ϕ vs. η');
7 Comments
Prachi
on 6 Aug 2023
Torsten
on 6 Aug 2023
Use "bvp4c" or "bvp5c". I don't know which MATLAB code uses the mentionned Keller Box scheme.
Prachi
on 6 Aug 2023
Torsten
on 6 Aug 2023
Your question is weird. Is it you who has to implement the Keller Box scheme ?
Prachi
on 7 Aug 2023
Torsten
on 7 Aug 2023
It should be clear that we won't program this for you.
If you have a boundary value problem as above, you can use the MATLAB tools "bvp4c" or "bvp5c".
If your problem is an assignment, you will have to start programming it in MATLAB or make a google search whether you find a MATLAB code that fits your needs.
Thiripura Sundari
on 27 Sep 2024
Good evening Professor, Shall we give matlab bvp4c code in jeffrey fluid thank you.
Santosh Devi
on 27 Feb 2024
0 votes
f^''' (η)+ff^'' (η)-(f^' (η))^2+Mf^' (η)-λf(η)=0
■θ^'' (η)+Pr[f(η)θ^' (η)-b/(u_w^2 ) ηθ(η)+Ec(f^'' (η))^2+Q_0 θ(η)]=0
■ϕ^'' (η)+Sc[f(η) ϕ^' (η)-Kϕ(η)]=0
■f(0)=s,f^' (0)=1,θ(0)=1,ϕ(0)=1
■f^' (∞)→0,θ(∞)→0,ϕ(∞)→0
5 Comments
Santosh Devi
on 27 Feb 2024
please give code for this
Santosh Devi
on 27 Feb 2024
function plot_velocity_vs_eta()
% Parameters
lambda = 0.1;
Pr = 0.72;
b = 1;
uw = 1;
Ec = 0.0001;
Q0 = 1;
Sc = 1;
K = 1;
s = 1;
M_values = [0, 0.5, 1];
% Initialize plot
figure;
hold on;
% Iterate over each Prandtl number
for i = 1:length(M_values)
M = M_values(i);
% Define the system of equations
equations = @(eta, y) [
y(2); % f'(eta) = y(2)
y(3); % f''(eta) = y(3)
-y(1)*y(3) + y(2)^2 - M*y(2) + lambda*y(1); % theta'(eta) = y(3)
-Pr * (y(1)*y(4) - b/(uw^2)*eta*y(3) + Ec*y(3)^2 + Q0*y(4)); % theta''(eta)
y(6); % phi'(eta) = y(6)
-Sc * (y(1)*y(6) - K*y(6)) % phi''(eta)
];
% Define the boundary conditions function
bc = @(ya, yb) boundary_conditions(ya, yb, s);
% Solve the equations
eta_span = [0, 10];
initial_conditions = [s; 0; 1; 1; 0; 0]; % Initial guesses for f, f', theta, phi, f'', phi'
options = odeset('RelTol', 1e-6, 'AbsTol', 1e-9);
[eta, solution] = ode45(equations, eta_span, initial_conditions, options);
% Calculate velocity (f'(eta))
velocity = solution(:, 2);
% Plot velocity against eta
plot(eta, velocity, '-', 'LineWidth', 2, 'DisplayName', sprintf('M = %.2f', M));
end
% Add labels and legend
xlabel('\eta');
ylabel('Velocity (f''(\eta))');
title('Velocity Profile for Different M Numbers');
legend('Location', 'best');
grid on;
hold off;
end
function res = boundary_conditions(ya, yb, s)
% Boundary conditions
res = [ya(1) - s; ya(2); ya(3) - 1; ya(5) - 1; ya(4); ya(6); yb(1) - s; yb(2); yb(3) - 1; yb(5) - 1; yb(4); yb(6)];
end
Torsten
on 27 Feb 2024
If you have code, what is your question ?
Thiripura Sundari
on 22 Oct 2024
Good afternoon Professor, can please give fourth order jeffrey fluid using keller box method
vijayakumar
on 30 Oct 2024
@Santosh Devi above code is which method
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