Trying to solve 2 dimensional Partial differential equation using Finite Difference Method

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Tristofani Agasta on 21 Mar 2022

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https://in.mathworks.com/matlabcentral/answers/1676354-trying-to-solve-2-dimensional-partial-differential-equation-using-finite-difference-method

Edited: Torsten on 14 May 2024

Currently I study about finite difference for 1d and 2d partial differential equation. I finish my code by trying to follow the algorithm my lecturer gave to me. The difference is, I add some conditional for some nodes which are located at boundaries (at the top and the right where the value supposedly be 1, not 0). But why my graph seems wrong? This method seems similar to Sandip Mazumder book and Youtube tutorial.

clc; clear all; close all
Ny=30;Nx=30;
dx=0.01;dy=0.01;
xa=0:dx:(Nx-1)*dx;
ya=0:dy:(Ny-1)*dy;
yb=(Ny-1)*dy:-dy:0;
xb=(Nx-1)*dx:-dx:0;
a=1/(dx)^2; c=1/(dy^2);
b=-2*(a+c);
%Create matrices A, B and solution
[A,B]= matriks(a, b,c, Nx, Ny);
solx =inv(A)*B;
for ii=1:Ny;
    for jj=1:Nx;
    k=(jj-1)*Ny+ii;
    sol(ii, jj)=solx(k);
    end
end
%Showing the graph
[X, Y] = meshgrid(xb, yb);
surface(X, Y, sol); colormap
shading interp; axis ('equal')
xlim([0 max(xa)]);ylim([0 max(ya)])
xlabel('Sumbu X'); ylabel('Sumbu Y')
function [A,B]=matriks(a,b,c,Nx,Ny)
B=zeros(Nx*Ny, 1);
A=eye(Nx*Ny);
dx=0.01
x=0:dx:1
y=0:dx:1
for ii=1:Nx;
    for jj=1:Ny
        if (ii>1) && (ii<Nx) && (jj>1) && (jj<Ny) % Insides
            k=(jj-1)*Ny+ii;
            B(k,1)=0;
            A(k,k)=b;
            A(k, k-1)=a;A(k,k+1)=a;
            A(k, k-Ny)=c;A(k, k+Ny)=c;
        elseif (jj==Ny) && (ii>1) && (ii<Nx) % Top boundary
            k=(jj-1)*Ny+ii;
            B(k,1)=y(jj);
            A(k,k)=b;
            A(k, k-1)=a;A(k,k+1)=a;
            A(k, k-Ny)=c;
        elseif ( ii==Nx ) &&( jj<Ny) && ( jj > 1 ) % Right boundary
            k=( jj - 1 )*Ny+ii;
            B( k , 1 )=x(jj);
            A( k , k )=b;
            A( k,  k - 1 )=a;
            if k < (Ny*Nx)-Ny
                A( k , k - Ny )=c;A(k, k+Ny)=c;
            end
        end
    end
end
end

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Answer 1

Torsten on 21 Mar 2022

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https://in.mathworks.com/matlabcentral/answers/1676354-trying-to-solve-2-dimensional-partial-differential-equation-using-finite-difference-method#answer_923154

Edited: Torsten on 21 Mar 2022

Open in MATLAB Online

For dx = dy = 0.01, Nx = Ny = 101, not 30 in your code. I just realized this after setting up the code below.

dx = 0.01;
dy = 0.01;
x = 0:dx:1;
y = 0:dy:1;
nx = numel(x);
ny = numel(y);
a =1/dx^2; 
c =1/dy^2;
b =-2*(a+c);
A = zeros(nx*ny,nx*ny);
B = zeros(nx*ny,1);
% Boundaries
% Boundary values at y = 0
for ix = 1:nx
    A(ix,ix) = 1.0;
    B(ix) = 0.0;
end
% Boundary values at x = 0
for iy = 2:ny-1
    k = nx*(iy-1) + 1;
    A(k,k) = 1.0;
    B(k) = 0.0;
end
% Boundary values at x = 1
for iy = 2:ny-1
    k = nx*iy;
    A(k,k) = 1.0;
    B(k) = y(iy);
end
% Boundary values at y = 1
for ix = 1:nx
    k = nx*(ny-1) + ix;
    A(k,k) = 1.0;
    B(k) = x(ix);
end
% Inner grid points
for iy = 2:ny-1
    for ix = 2:nx-1
        k = (iy-1)*nx + ix;
        A(k,k) = b;
        A(k,k+1) = a;
        A(k,k-1) = a;
        A(k,k+nx) = c;
        A(k,k-nx) = c;
    end
end
u = A\B;
%u
U = zeros(nx,ny);
for iy = 1:ny
    for ix = 1:nx
        k = (iy-1)*nx + ix;
        U(ix,iy) = u(k);
    end
end
[X,Y] = meshgrid(x,y);
surf(X, Y, U); 

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Torsten on 22 Mar 2022

Edited: Torsten on 22 Mar 2022

Which iterations do you mean ? The loops to set up A and B ?

Tristofani Agasta on 23 Mar 2022

Both A and B, I thought I can put all nodes on each boundary in same 'for' loop. I never thought I can use for ii and for jj for each boundary separately, with different k index

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Answer 2

Torsten on 27 Sep 2023

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https://in.mathworks.com/matlabcentral/answers/1676354-trying-to-solve-2-dimensional-partial-differential-equation-using-finite-difference-method#answer_1320434

Open in MATLAB Online

For those who might be interested in a finite volume code for the equation above.

Skerdi Hymeraj asked for such code, but deleted the given answer.

dx = 0.01;
dy = 0.01;
x = dx/2:dx:1-dx/2;
y = dy/2:dy:1-dy/2;
nx = numel(x);
ny = numel(y);
%A = zeros(nx*ny);
b = zeros(nx*ny,1);
index = 0;
% Points in contact to boundaries
% i = 1, j = 1
k = 1;
index = index + 1;
irc(index) = k;
icc(index) = k;
mat(index) = ( -dy/dx - dy/(dx/2) - dx/dy - dx/(dy/2) );
index = index + 1;
irc(index) = k;
icc(index) = k+1;
mat(index) = dy/dx;
index = index + 1;
irc(index) = k;
icc(index) = k+nx;
mat(index) = dx/dy;
%A(k,k) = ( -dy/dx - dy/(dx/2) - dx/dy - dx/(dy/2) );
%A(k,k+1) = dy/dx;
%A(k,k+nx) = dx/dy;
b(k) = -dy/(dx/2) * bcfun(0,y(1)) -dx/(dy/2) * bcfun(x(1),0);
% i = nx, j = 1
k = nx;
index = index + 1;
irc(index) = k;
icc(index) = k;
mat(index) = ( -dy/(dx/2) - dy/dx - dx/dy - dx/(dy/2) );
index = index + 1;
irc(index) = k;
icc(index) = k-1;
mat(index) = dy/dx;
index = index + 1;
irc(index) = k;
icc(index) = k + nx;
mat(index) = dx/dy;
%A(k,k) = ( -dy/(dx/2) - dy/dx - dx/dy - dx/(dy/2) );
%A(k,k-1) = dy/dx;
%A(k,k+nx) = dx/dy;
b(k) = -dy/(dx/2) * bcfun(1,y(1)) -dx/(dy/2) * bcfun(x(nx),0);
% i = 1, j = ny
k = (ny-1)*nx+1;
index = index + 1;
irc(index) = k;
icc(index) = k;
mat(index) = (-dy/dx - dy/(dx/2) - dx/(dy/2) - dx/dy);
index = index + 1;
irc(index) = k;
icc(index) = k+1;
mat(index) = dy/dx;
index = index + 1;
irc(index) = k;
icc(index) = k-nx;
mat(index) = dx/dy;
%A(k,k) = (-dy/dx - dy/(dx/2) - dx/(dy/2) - dx/dy);
%A(k,k+1) = dy/dx;
%A(k,k-nx) = dx/dy;
b(k) = -dy/(dx/2) * bcfun(0,y(ny)) -dx/(dy/2) * bcfun(x(1),1);
% i = nx, j = ny
k = nx*ny;
index = index + 1;
irc(index) = k;
icc(index) = k;
mat(index) = (-dy/(dx/2) - dy/dx - dx/(dy/2) - dx/dy);
index = index + 1;
irc(index) = k;
icc(index) = k-1;
mat(index) = dy/dx;
index = index + 1;
irc(index) = k;
icc(index) = k-nx;
mat(index) = dx/dy;
%A(k,k) = (-dy/(dx/2) - dy/dx - dx/(dy/2) - dx/dy);
%A(k,k-1) = dy/dx;
%A(k,k-nx) = dx/dy;
b(k) = -dy/(dx/2) * bcfun(1,y(ny)) -dx/(dy/2) * bcfun(x(nx),1);
% 1 < i < nx, j = 1
for ix = 2:nx-1
  k = ix;
  index = index + 1;
  irc(index) = k;
  icc(index) = k;
  mat(index) = -dy/dx - dy/dx - dx/dy -dx/(dy/2);
  index = index + 1;
  irc(index) = k;
  icc(index) = k-1;
  mat(index) = dy/dx;
  index = index + 1;
  irc(index) = k;
  icc(index) = k+1;
  mat(index) = dy/dx;
  index = index + 1;
  irc(index) = k;
  icc(index) = k+nx;
  mat(index) = dx/dy;
  %A(k,k) = -dy/dx - dy/dx - dx/dy -dx/(dy/2);
  %A(k,k-1) = dy/dx;
  %A(k,k+1) = dy/dx;
  %A(k,k+nx) = dx/dy;
  b(k) = -dx/(dy/2) * bcfun(x(ix),0);
end
% 1 < i < nx, j = ny
for ix = 2:nx-1
  k = (ny-1)*nx + ix;
  index = index + 1;
  irc(index) = k;
  icc(index) = k;
  mat(index) = -dy/dx -dy/dx -dx/(dy/2) -dx/dy;
  index = index + 1;
  irc(index) = k;
  icc(index) = k-1;
  mat(index) = dy/dx;
  index = index + 1;
  irc(index) = k;
  icc(index) = k+1;
  mat(index) = dy/dx;
  index = index + 1;
  irc(index) = k;
  icc(index) = k-nx;
  mat(index) = dx/dy;
  %A(k,k) = -dy/dx -dy/dx -dx/(dy/2) -dx/dy;
  %A(k,k-1) = dy/dx;
  %A(k,k+1) = dy/dx;
  %A(k,k-nx) = dx/dy;
  b(k) = -dx/(dy/2) * bcfun(x(ix),1);
end
% i = 1, 1 < j < ny
for iy = 2:ny-1
  k = 1 + (iy-1)*nx;
  index = index + 1;
  irc(index) = k;
  icc(index) = k;
  mat(index) = -dy/dx - dy/(dx/2) - dx/dy - dx/dy;
  index = index + 1;
  irc(index) = k;
  icc(index) = k+1;
  mat(index) = dy/dx;
  index = index + 1;
  irc(index) = k;
  icc(index) = k-nx;
  mat(index) = dx/dy;
  index = index + 1;
  irc(index) = k;
  icc(index) = k+nx;
  mat(index) = dx/dy;
  %A(k,k) = -dy/dx - dy/(dx/2) - dx/dy - dx/dy;
  %A(k,k+1) = dy/dx;
  %A(k,k-nx) = dx/dy;
  %A(k,k+nx) = dx/dy;
  b(k) = -dy/(dx/2) * bcfun(0,y(iy));
end
% i = nx, 1 < j < ny
for iy = 2:ny-1
  k = nx*iy;
  index = index + 1;
  irc(index) = k;
  icc(index) = k;
  mat(index) = -dy/(dx/2) - dy/dx - dx/dy - dx/dy;
  index = index + 1;
  irc(index) = k;
  icc(index) = k-1;
  mat(index) = dy/dx;
  index = index + 1;
  irc(index) = k;
  icc(index) = k-nx;
  mat(index) = dx/dy;
  index = index + 1;
  irc(index) = k;
  icc(index) = k+nx;
  mat(index) = dx/dy;
  %A(k,k) = -dy/(dx/2) - dy/dx - dx/dy - dx/dy;
  %A(k,k-1) = dy/dx;
  %A(k,k-nx) = dx/dy;
  %A(k,k+nx) = dx/dy;
  b(k) = -dy/(dx/2) * bcfun(1,y(iy));
end
% Inner grid points
% 1 < ix < nx, 1 < iy < ny
for ix = 2:nx-1
  for iy = 2:ny-1
    k = (iy-1)*nx + ix;
    index = index + 1;
    irc(index) = k;
    icc(index) = k;
    mat(index) = -dy/dx - dy/dx - dx/dy - dx/dy;
    index = index + 1;
    irc(index) = k;
    icc(index) = k+1;
    mat(index) = dy/dx;
    index = index + 1;
    irc(index) = k;
    icc(index) = k-1;
    mat(index) = dy/dx;
    index = index + 1;
    irc(index) = k;
    icc(index) = k+nx;
    mat(index) = dx/dy;
    index = index + 1;
    irc(index) = k;
    icc(index) = k-nx;
    mat(index) = dx/dy;
    %A(k,k) = -dy/dx - dy/dx - dx/dy - dx/dy;
    %A(k,k+1) = dy/dx;
    %A(k,k-1) = dy/dx;
    %A(k,k+nx) = dx/dy;
    %A(k,k-nx) = dx/dy;
    b(k) = 0;
  end
end
A = sparse(irc,icc,mat,nx*ny,nx*ny);
u = A\b;
%u
U = zeros(nx,ny);
for iy = 1:ny
    for ix = 1:nx
        k = (iy-1)*nx + ix;
        U(ix,iy) = u(k);
    end
end
[X,Y] = meshgrid(x,y);
surf(X, Y, U, 'EdgeColor','none');
end
function bc_value = bcfun(x,y)
  if x==0 || y == 0
    bc_value = 0;
    return
  end
  if x==1
    bc_value = y;
    return
  end
  if y==1
    bc_value = x;
    return
  end
end

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skerdi hymeraj on 28 Sep 2023

sorry I have no idea how to use this site

Torsten on 28 Sep 2023

Edited: Torsten on 14 May 2024

The internet doesn't forget:

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Trying to solve 2 dimensional Partial differential equation using Finite Difference Method

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Trying to solve 2 dimensional Partial differential equation using Finite Difference Method

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