Need help solving heat equation using adi method
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Nx = 50;
Ny = 50;
dx = 1.0 / (Nx - 1);
dy = 2.0 / (Ny - 1);
T = 0.00001;
dt = 0.000000001;
Nt = 1000; % Total number of time steps
alpha = 4; % Diffusion coefficient
x = linspace(0, 1, Nx);
y = linspace(0, 2, Ny);
[X, Y] = meshgrid(x, y);
U = Y .* X + 1; % Initial condition
function val = f(x, y, t)
val = exp(t) * cos(pi * x / 2) * sin(pi * y / 4);
end
function U = apply_boundary_conditions(U, x, y, dy, dx)
U(:, 1) = 1; % y=0
U(:, end) = U(:, end-1) + dy .* x'; % y=2
U(1, :) = U(2, :) - dx * y; % x=0
U(end, :) = y' + 1; % x=1
end
% Thomas algorithm
function x = thomas_algorithm(a, b, c, d)
n = length(d);
c_star = zeros(n-1, 1);
d_star = zeros(n, 1);
x = zeros(n, 1);
c_star(1) = c(1) / b(1);
d_star(1) = d(1) / b(1);
for i = 2:n-1
temp = b(i) - a(i-1) * c_star(i-1);
c_star(i) = c(i) / temp;
d_star(i) = (d(i) - a(i-1) * d_star(i-1)) / temp;
end
d_star(n) = (d(n) - a(n-1) * d_star(n-1)) / b(n);
x(n) = d_star(n);
for i = n-1:-1:1
x(i) = d_star(i) - c_star(i) * x(i+1);
end
end
% ADI method
for n = 1:Nt
U = apply_boundary_conditions(U, x, y, dy, dx);
% First half-step: X-direction implicit, Y-direction explicit
for j = 2:Ny-1
a = -alpha * dt / (2 * dx^2) * ones(Nx-1, 1);
b = (1 + alpha * dt / dx^2) * ones(Nx, 1);
c = -alpha * dt / (2 * dx^2) * ones(Nx-1, 1);
d = U(j, 2:end-1)' + 0.5 * alpha * dt / dy^2 * (U(j+1, 2:end-1) - 2 * U(j, 2:end-1) + U(j-1, 2:end-1))' + dt * f(x(2:end-1), y(j), n*dt);
U(j, 2:end-1) = thomas_algorithm(a, b(2:end-1), c, d);
end
% Second half-step: Y-direction implicit, X-direction explicit
for i = 2:Nx-1
a = -alpha * dt / (2 * dy^2) * ones(Ny-1, 1);
b = (1 + alpha * dt / dy^2) * ones(Ny, 1);
c = -alpha * dt / (2 * dy^2) * ones(Ny-1, 1);
d = U(2:end-1, i) + 0.5 * alpha * dt / dx^2 * (U(2:end-1, i+1) - 2 * U(2:end-1, i) + U(2:end-1, i-1)) + dt * f(x(i), y(2:end-1), n*dt);
U(2:end-1, i) = thomas_algorithm(a, b(2:end-1), c, d);
end
U = apply_boundary_conditions(U, x, y, dy, dx);
end
% Visualization
surf(X, Y, U);
title('ADI Solution at T=' + string(T));
xlabel('X');
ylabel('Y');
zlabel('U');
colorbar;
1 Comment
Torsten
on 12 May 2024
Shouldn't your solution array be three-dimensional instead of two-dimensional ? The way you arranged the code, you only get one solution at time T - the complete history for U is overwritten.
Answers (1)
John D'Errico
on 12 May 2024
You say it works for sufficiently small values dt.
With that exp(t) term in there, do you seriously expect it to work well for large values of dt? I have dreams myself somedays...
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