PDE Numerical Solver Using Finite Differences
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Hey everyone, I'm working on the following problem:
Solve Laplace's equation on the heating 3 by 3 heating block with the boundary conditions of 75, 100, 50, and 0. This is to be done by using the Liebmann method with an over-relaxation factor of 1.5 and and a stopping criteria (relative error) of 1%.
So far, my code looks like this: ________________________________________________________________________________________________
% This will attempt to solve the Laplace equation with the given Dirichlet
% conditions.
% We will use the Liebmann Method, which will employ the usage of the
% following equation:
% T(i,j) = ( T(i+1,j) + T(i-1,j) + T(i,j+1) + T(i,j-1) )/4
% We will also employ overrelaxation
% T(i,j,new) = l*T(i,j,new) + (1-l)*T(i,j,old)
% Where l is the overrelaxation factor.
% Along with the error condition
%
% |e(a,i,j)| = (T(i,j,new) - T(i,j,old))
% __________________________ * 100%
% T(i,j,new)
% Boundary condition Matrix
T = zeros(5,5);
T(:,1) = 75;
T(:,5) = 50;
T(5,2) = 100;
T(5,3) = T(5,2);
T(5,4) = T(5,3);
T(1,1) = 75/2;
T(1,5) = 150/2;
T(5,5) = 50/2;
T(5,1) = 75/2;
l = 1.5; % weighting factor
e = 0.01; % desired error
for i = 2:4
for j = 2:4
T(i,j) = (T((i+1),j) + T((i-1),j) + T(i,(j-1)) + T(i,(j+1)))./4;
T(i,j) = l.*T(i,j);
end
end
disp(['The new matrix should look like'])
disp(T)
______________________________________________________________________________________________
This gets me as far as the first iteration. But to get the final solution the program requires I need about nine iterations, but how do I employ the overrelaxation and the error condition in this to generate the final values?
All help is greatly appreciated.
Thanks!
1 Comment
Alberto
on 17 Dec 2014
You should include your double for loop inside a while that controls the iteration, so it can be runned several times.
You should create an absolute error variable that calculates the difference beetween 2 diferent iterations (you should save the old one ) and use norm to determine the difference, and a tolerance variable.
Answers (2)
pshymn
on 8 Mar 2017
Edited: pshymn
on 8 Mar 2017
% Lecture: Sayisal Isi Gecisi ve Akis 2
% Source: Numerical method for engineers, Chapra&Canale, 6th edition
% Example 29.1
% Method used: Liebmann Method (Gauss-Seidel Method)
T_ust=100; %top-side temperature of heated plate
T_sol=75; %left-side temperature of heated plate
T_sag=50; %right-side temperature of heated plate
T_alt=0; %bottom-side temperature of heated plate
n=100; %m and n are the dimension of the matrices, so it can be any number such as 10, 20...
m=100;
L=1.5; %overrelaxation value
T=zeros(m,n,'double');
T1=zeros(m,n,'double');
for i=1:m %here, the up&bottom-sides are defined.
T(i,1)=T_alt;
T(i,n)=T_ust;
end
for j=1:n %again, left and right sides are defined.
T(1,j)=T_sol;
T(m,j)=T_sag;
end
for i=2:m-1 %the nods whose temperatures will be found are defined. they are nods in the middle.
for j=2:n-1
T(i,j)=50;
T(i,j)=50;
end
end
for k=1:1000 %this is the iteration number,you can keep it around 20-30.but to be sure it's 1000.
for i=2:m-1
for j=2:n-1
T1(i,j)=0.25*(T((i+1),j) + T((i-1),j) + T(i,(j-1)) + T(i,(j+1))); %formula1
T(i,j)=L*T1(i,j)+(1-L)*T(i,j); %formula2
end
end
end
%Draw a graph
x=0:1/(m-1):1;
y=0:1/(n-1):1;
t2d=transpose(T);
contourf(x,y,t2d, 30)
xlabel({'X [metre]'});
ylabel({'Y [metre]'});
title('TEMPERATURE DISTRIBUTION IN THE PLATE')
% at the end, there will be a .fig file which demonstrates temperature distribution in colorful window.
1 Comment
Ashley Turner
on 3 Dec 2019
What is the top boundary was a function? I can you incorporate that into the code..
i.e - The upper boundary: T=f(x)=ax-x^2
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