I ran the code just to see what it does and what the problem could be.
Perhaps if you could post ‘Example # 2 on Versteeg 2E book Pages 135-139’ (without violating any copyright) it would be easier to see what the problem is. (I am not aware of that book. Since I do not have it in my library, I cannot refer to it.)
%% Sort out Inputs
tic
% Number of Control Volumes
N = 5;
% Domain length
L = 0.02; %[m]
% Grid Spacing
h = L/(N);
% Diffusivity (Thermal conductivity)
k = 0.5; %[W/m-K]
% Uniform Heat Generation, A Source Term
q = 1000e3; % [W/m^(3)]
% The center of the first cell is at dx/2 & the last cell is at L-dx/2.
x = h/2 : h : L-(h/2);
% Cross sectional area of the 1D domain
A = 1; %[m^2]
% Left Boundary Condition
T_a = 100; %[\circ c]
% Right Boundary Condition
T_b = 200; %[\circ c]
% Initialising Temperature
T=zeros(N,1);
% Left Boundary Condition
T(1)= 100; %[\circ c]
% Right Boundary Condition
T(N) = 200; %[\circ c]
% Interior of Domain
index_x = 2:N-1;
%% Formation of Coefficient Matrices, Numerical Solution
% Tolerence
eps = 1.e-6;
% Iteration
It = 0;
T_old = T;
Error = 2*eps;
% Calculation
while (Error > eps)
It = It +1;
T(index_x)= 0.5*(T(index_x-1) + T(index_x+1)+ (q*h*h)/(k));
Error = max(abs(T(:)-T_old(:)));
if any(isnan(T(:))) || any(isinf(T(:)))
fprintf(' Iteration Diverge \n');
return;
end
T_old = T;
end
T_Numeric = T;
%% Analytical Results
X_G = x;
T_Analytical=((T_b-T_a)/L + (q/(2*k))*( L - X_G )).*(X_G) + T_a;
%% Error Analysis
M_Error(N)=0;
for i=1:N
% This x is only use to compare results on Versteeg book
k=find(abs(X_G - x(i))<=1e-3);
% No need to find k (You can but no Need)
% Absolute Error
M_Error(i) = abs(T_Numeric(i)-T_Analytical(i));
% Relative Error
Relative_Error(i) = abs(T_Numeric(i)-T_Analytical(i))/abs(T_Numeric(i));
% Percentage Error
Percentage_Error(i) = Relative_Error(i).*100;
end
%% Post Processing
% Data Table Comparison of Different Results
Nodes = 1 : N;
fprintf('Node Grid_{Loc.} T_{Num.} T_{An.} Error\n\n');
fprintf('====================================================\n');
for i = 1: N;
fprintf('%3.0f %3.5f %3.5f %3.5f %3.5f\n',[Nodes(i); X_G(i); T_Numeric(i); T_Analytical(i); Percentage_Error(i)]);
end
% Graphical Representation
plot(100*x,T_Numeric,'--','MarkerSize',5,'MarkerFaceColor','b');
% hold on
% plot([0, 100.*L], [T_a, T_b], 'd', 'LineWidth',3,'MarkerFaceColor','b');
hold on
plot(100*X_G,T_Analytical,'r','LineWidth',2);
% hold on
% plot([0, 100.*L], [T_a, T_b], 'd', 'LineWidth',3,'MarkerFaceColor','r');
% xlim([0 2]);
% ylim([50 300]);
%Boundary Points Inclusion
xlabel('Distance (m)');
ylabel('Temperature [\circ C]');
legend('T_{Numeric}','T_{Analytical}', 'Location','best');
title ('Numerical & Analytical Results Comparison');
grid on;
figure
plot(T_Analytical, T_Numeric, '+')
hold on
p = polyfit(T_Analytical, T_Numeric, 1)
pv = polyval(p, T_Analytical);
plot(T_Analytical, pv, '--k')
hold off
grid
I added the last plot simply to see if there is any consistent relationship.
.
