%MAC algorithm based code developed by Rohit Kanchi
%Contact: +91 91081 52106
%All units are in SI System kg,m,s,K,Pa
clc
clear
close all
savepath='D:\CFD_MEE4006\Project\2D MAC Algorithm FDM Code\Simulation_Files\';
fprintf("This is an FDM MAC algorithm based code to predict 2-D unsteady incompressible viscous flows. \n\n");
fprintf("Please make sure to enter the input parameters correctly");
nx=100;
ny=40;
deltax=1;
deltay=1;
a=deltax;
b=deltay;
deltaT=0.001;
timesteps=1000;
mu=10^(-3);
rho=1000;
%Grid Point Generator
[Pgrid,Ugrid,Vgrid]=gridpointgenerator(nx,ny,deltax,deltay);
%Boundary Conditions:
%Top: Slip Wall [Axis of rotation]
%Bottom: No Slip Wall, Adiabatic
%Left: Velocity Inlet
Inletvel=0.1;
%Right: Pressure Boundary Condition
ExitP=101325;
%Grid Points Initialization at t=0s
%Pressure Grid Points:
l=length(Pgrid(:,1));
for i=1:l
Pgrid(i,3)=ExitP;
end
%u vel grid points:
l=length(Ugrid(:,1));
for i=1:l
if Ugrid(i,1)==(-(deltax/2))
Ugrid(i,3)=Inletvel;
else
Ugrid(i,3)=0;
end
end
%v vel grid points:
l=length(Vgrid(:,1));
for i=1:l
Vgrid(i,3)=0;
end
%%%% START MAC ALGORITHM
utild=Ugrid+0; %Initializing Provisional Velocity matrices
vtild=Vgrid+0;
Pprime=Pgrid+0;
Ugridtemp=Ugrid+0;
Vgridtemp=Vgrid+0;
for timestep=1:timesteps
flag=0; %This var, if zero, means residual are not sufficiently low.
%When the residual comes down in the while loop below, a break-
%-statement is encountered and the soln proceeds to next time-
%-step after updating values
iter=1;
while flag==0
%Calculate provisional velocities:
%Calculate U~
for i=1:length(Ugrid(:,1))
if Ugrid(i,1)==(-(deltax/2)) %Left Boundary
continue
elseif Ugrid(i,1)==((nx*deltax)-(deltax/2)) %Right Boundary
continue
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
elseif Ugrid(i,2)==0 && Ugrid(i,1)~=((nx*deltax)-(deltax/2)) %Bottom Boundary
u1=Ugrid(i,3); %i,j
u2=Ugrid(i+1,3); %i+1,j
u3=Ugrid(i-1,3); %i-1,j
%i,j+1
for k=i:length(Ugrid(:,1))
if(Ugrid(k,1))==(Ugrid(i,1))
u4=Ugrid(k,3);
break
end
end
%i,j-1
u5=0-u1;
%v Velocity points for averaging
for k=1:length(Vgrid(:,1))
if Vgrid(k,1)==Ugrid(i,1)-(deltax/2) && Vgrid(k,2)==Ugrid(i,2)+(deltay/2)
vforavg1=Vgrid(k,3); %i,j
elseif Vgrid(k,1)==Ugrid(i,1)+(deltax/2) && Vgrid(k,2)==Ugrid(i,2)+(deltay/2)
vforavg2=Vgrid(k,3); %i+1,j
end
end
vforavg3=0;
vforavg4=0;
%Calculate Pressures:
for k=1:length(Pgrid(:,1))
if Pgrid(k,1)==Ugrid(i,1)+(deltax/2) && Pgrid(k,2)==Ugrid(i,2)
P1up=Pgrid(k,3); %P i+1,j
end
if Pgrid(k,1)==Ugrid(i,1)-(deltax/2) && Pgrid(k,2)==Ugrid(i,2)
P2up=Pgrid(k,3); %P i,j
end
end
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
elseif Ugrid(i,2)==((ny*deltay)-deltay) && Ugrid(i,1)~=((nx*deltax)-(deltax/2)) %Top Boundary
u1=Ugrid(i,3); %i,j
u2=Ugrid(i+1,3); %i+1,j
u3=Ugrid(i-1,3); %i-1,j
%i,j+1
u4=u1+0;
%i,j-1
for k=i:-1:1
if(Ugrid(k,1))==(Ugrid(i,1))
u5=Ugrid(k,3);
break
end
end
%v Velocity points for averaging
for k=1:length(Vgrid(:,1))
if Vgrid(k,1)==Ugrid(i,1)-(deltax/2) && Vgrid(k,2)==Ugrid(i,2)+(deltay/2)
vforavg1=Vgrid(k,3); %i,j
elseif Vgrid(k,1)==Ugrid(i,1)+(deltax/2) && Vgrid(k,2)==Ugrid(i,2)+(deltay/2)
vforavg2=Vgrid(k,3); %i+1,j
elseif Vgrid(k,1)==Ugrid(i,1)+(deltax/2) && Vgrid(k,2)==Ugrid(i,2)-(deltay/2)
vforavg3=Vgrid(k,3); %i+1,j-1
elseif Vgrid(k,1)==Ugrid(i,1)-(deltax/2) && Vgrid(k,2)==Ugrid(i,2)-(deltay/2)
vforavg4=Vgrid(k,3); %i-1,j-1
end
end
%Calculate Pressures:
for k=1:length(Pgrid(:,1))
if Pgrid(k,1)==Ugrid(i,1)+(deltax/2) && Pgrid(k,2)==Ugrid(i,2)
P1up=Pgrid(k,3); %P i+1,j
end
if Pgrid(k,1)==Ugrid(i,1)-(deltax/2) && Pgrid(k,2)==Ugrid(i,2)
P2up=Pgrid(k,3); %P i,j
end
end
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
else %Interior Grid Points
u1=Ugrid(i,3); %i,j
u2=Ugrid(i+1,3); %i+1,j
u3=Ugrid(i-1,3); %i-1,j
%i,j+1
for k=i:length(Ugrid(:,1))
if(Ugrid(k,1))==(Ugrid(i,1))
u4=Ugrid(k,3);
break
end
end
%i,j-1
for k=i:-1:1
if(Ugrid(k,1))==(Ugrid(i,1))
u5=Ugrid(k,3);
break
end
end
%v Velocity points for averaging
for k=1:length(Vgrid(:,1))
if Vgrid(k,1)==Ugrid(i,1)-(deltax/2) && Vgrid(k,2)==Ugrid(i,2)+(deltay/2)
vforavg1=Vgrid(k,3); %i,j
elseif Vgrid(k,1)==Ugrid(i,1)+(deltax/2) && Vgrid(k,2)==Ugrid(i,2)+(deltay/2)
vforavg2=Vgrid(k,3); %i+1,j
elseif Vgrid(k,1)==Ugrid(i,1)+(deltax/2) && Vgrid(k,2)==Ugrid(i,2)-(deltay/2)
vforavg3=Vgrid(k,3); %i+1,j-1
elseif Vgrid(k,1)==Ugrid(i,1)-(deltax/2) && Vgrid(k,2)==Ugrid(i,2)-(deltay/2)
vforavg4=Vgrid(k,3); %i-1,j-1
end
end
%Calculate Pressures:
for k=1:length(Pgrid(:,1))
if Pgrid(k,1)==Ugrid(i,1)+(deltax/2) && Pgrid(k,2)==Ugrid(i,2)
P1up=Pgrid(k,3); %P i+1,j
end
if Pgrid(k,1)==Ugrid(i,1)-(deltax/2) && Pgrid(k,2)==Ugrid(i,2)
P2up=Pgrid(k,3); %P i,j
end
end
end
delcU= rho*((u1*((u2-u3)/(2*a))) + (((vforavg1+vforavg2+vforavg3+vforavg4)/4)*((u4-u5)/(2*b))));
deldU= mu*( ((u2-(2*u1)+u3)/(a^2)) + ((u4-(2*u1)+u5)/(b^2)));
%Calc provisional Up:
utild(i,3)= u1 + ((deltaT/rho)* (deldU-delcU + ((P2up-P1up)/a)));
end
%Calculate V~
for i=1:length(Vgrid(:,1))
if Vgrid(i,1)==0 || Vgrid(i,1)==((nx-1)*deltax) || Vgrid(i,2)==(0-(deltay/2)) || Vgrid(i,2)==((ny*deltay)-(deltay/2)) %left, right, bottom and top boundaries
continue
else %Interior grid points
v1=Vgrid(1,3); %i,j
for k=1:length(Vgrid(:,1)) %i,j+1
if Vgrid(k,1)==Vgrid(i,1) && Vgrid(k,2)==(Vgrid(i,2)+deltay)
v2=Vgrid(k,3);
break;
end
end
for k=1:length(Vgrid(:,1)) %i,j-1
if Vgrid(k,1)==Vgrid(i,1) && Vgrid(k,2)==(Vgrid(i,2)-deltay)
v3=Vgrid(k,3);
break;
end
end
v4=Vgrid(i+1,3); %i+1,j
v5=Vgrid(i-1,3); %i-1,j
%calc u vel avg
for k=1:length(Ugrid(:,1))
if Ugrid(k,1)==Vgrid(i,1)-(deltax/2) && Ugrid(k,2)==Vgrid(i,2)+(deltay/2)
uforavg1=Ugrid(k,3); %i,j
elseif Ugrid(k,1)==Vgrid(i,1)+(deltax/2) && Ugrid(k,2)==Vgrid(i,2)+(deltay/2)
uforavg2=Ugrid(k,3); %i+1,j
elseif Ugrid(k,1)==Vgrid(i,1)+(deltax/2) && Ugrid(k,2)==Vgrid(i,2)-(deltay/2)
uforavg3=Ugrid(k,3); %i+1,j-1
elseif Ugrid(k,1)==Vgrid(i,1)-(deltax/2) && Ugrid(k,2)==Vgrid(i,2)-(deltay/2)
uforavg4=Ugrid(k,3); %i-1,j-1
end
end
%Calc Pressures
for k=1:length(Pgrid(:,1))
if Pgrid(k,1)==Vgrid(i,1) && Pgrid(k,2)==(Vgrid(i,2)-(deltay/2))
P1vp=Pgrid(k,3); %P i,j
end
if Pgrid(k,1)==Vgrid(i,1) && Pgrid(k,2)==(Vgrid(i,2)+(deltay/2))
P2vp=Pgrid(k,3); %P i,j+1
end
end
end
delcV=rho*( (v1*((v2-v3)/(2*b))) + (((uforavg1+uforavg2+uforavg3+uforavg4)/4)*((v4-v5)/(2*a))) );
deldV=mu*( ((v4-(2*v1)+v5)/(a^2)) + ((v2-(2*v1)+v3)/(b^2)) );
vtild(i,3)=v1 + ((deltaT/rho)* (deldV-delcV + ((P1vp-P2vp)/b)));
end
%Calculate P' field
for i=1:length(Pgrid(:,1))
px1=Pgrid(i,1)+(deltax/2);
px2=Pgrid(i,1)-(deltax/2);
py1=Pgrid(i,2)+(deltay/2);
py2=Pgrid(i,2)-(deltay/2);
for k=1:length(utild(:,1))
if utild(k,1)==px1 && utild(k,2)==Pgrid(i,2)
up=utild(k,3);
end
if utild(k,1)==px2 && utild(k,2)==Pgrid(i,2)
uw=utild(k,3);
end
end
for k=1:length(vtild(:,1))
if vtild(k,1)==Pgrid(i,1) && vtild(k,2)==py1
vp=vtild(k,3);
end
if vtild(k,1)==Pgrid(i,1) && vtild(k,2)==py2
vs=vtild(k,3);
end
end
Pprime(i,3)= -(( ((up-uw)/a) +((vp-vs)/b) )/( ((2*deltaT)/rho)*((1/(a^2)) + (1/(b^2))) ));
end
%Updating utild and vtild to n+1 temporarily to check for-
%-convergence
for i=1:length(Ugrid(:,1))
if Ugrid(i,1)==(-(deltax/2)) || Ugrid(i,1)==((nx*deltax)-(deltax/2)) %Left Boundary and right boundary
continue
end
for k=1:length(Pprime(:,1))
if Pprime(k,1)==Ugrid(i,1)-((deltax)/2) && Pprime(k,2)==Ugrid(i,2)
Ugridtemp(i,3)=utild(i,3) - ( (deltaT/(rho*a))*(Pprime(k+1,3)-Pprime(k,3)));
end
end
end
%For right boundary we need special treatment for uvel:
for i=1:length(Ugrid(:,1))
if Ugrid(i,1)==((nx*deltax)-(deltax/2))
Ugridtemp(i,3)=Ugridtemp(i-1,3);
end
end
for i=1:length(Vgrid(:,1))
if Vgrid(i,1)==0 || Vgrid(i,1)==((nx-1)*deltax) || Vgrid(i,2)==(0-(deltay/2)) || Vgrid(i,2)==((ny*deltay)-(deltay/2)) %left, right, bottom and top boundaries
continue
end
for k=1:length(Pprime(:,1))
if Pprime(k,1)==Vgrid(i,1) && Pprime(k,2)==(Vgrid(i,2)-(deltay/2))
paa=Pprime(k,3);
elseif Pprime(k,1)==Vgrid(i,1) && Pprime(k,2)==(Vgrid(i,2)+(deltay/2))
pbb=Pprime(k,3);
end
end
Vgridtemp(i,3)=vtild(i,3) - ( (deltaT/(rho*b))*(pbb-paa));
end
%For right and top boundary we need special treatment for vvel:
for i=1:length(Vgrid(:,1))
if Vgrid(i,1)==((nx-1)*deltax) %right
Vgridtemp(i,3)=Vgrid(i-1,3);
elseif Vgrid(i,1)==((ny*deltay)-(deltay/2)) %top
for k=1:length(Vgrid(:,1))
if Vgrid(k,1)==Vgrid(i,1) && Vgrid(k,2)==(Vgrid(i,2)-deltay)
Vgridtemp(i,3)=Vgrid(k,3);
end
end
end
end
%Pressure correction
for i=1:length(Pgrid(:,1))
if Pgrid(i,1)==((nx-1)*deltax)
continue
else
Pgrid(i,3)=Pgrid(i,3)+Pprime(i,3);
end
end
%To ensure dp/dy at boundary is zero:
%Check for convergence using temporary values:
%[Convergence Check: L1 norm]
sum=0;
for i=1:length(Pgrid(:,1))
px1=Pgrid(i,1)+(deltax/2);
px2=Pgrid(i,1)-(deltax/2);
py1=Pgrid(i,2)+(deltay/2);
py2=Pgrid(i,2)-(deltay/2);
for k=1:length(Ugridtemp(:,1))
if Ugridtemp(k,1)==px1 && Ugridtemp(k,2)==Pgrid(i,2)
up=Ugridtemp(k,3);
end
if Ugridtemp(k,1)==px2 && Ugridtemp(k,2)==Pgrid(i,2)
uw=Ugridtemp(k,3);
end
end
for k=1:length(Vgridtemp(:,1))
if Vgridtemp(k,1)==Pgrid(i,1) && Vgridtemp(k,2)==py1
vp=Vgridtemp(k,3);
end
if Vgridtemp(k,1)==Pgrid(i,1) && Vgridtemp(k,2)==py2
vs=Vgridtemp(k,3);
end
end
residual=( ((up-uw)/a) +((vp-vs)/b) );
sum=sum+abs(residual);
end
m=sum/length(Pgrid(:,1));
disp(m);
%disp(iter);
if m<=0.001 %Converged
flag=1;
Vgrid=Vgridtemp; %Proceeding to n+1
Ugrid=Ugridtemp;
else %Not converged
iter=iter+1;
end
end
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%Proceeding to next time step n -> n+1:
%The points in the u and v grids are first updated.
%While updation, points such as the inlet grid points for uvel are-
%-not touched because they are constant vel points and is a -
%-dirichlet bc.
%Similarly the Pgrid is also updated and the exit P points are not-
%-touched because it is a constant pressure Dirichlet BC
%Save files at n+1 for the current time-step
if mod((timestep*deltaT),0.01)==0
file_name = sprintf('U_vel_timestep_%d.txt',timestep);
id=fopen([savepath file_name],'w');
for i=1:length(Ugrid(:,1))
fprintf(id,'%f %f %f\n',Ugrid(i,1),Ugrid(i,2),Ugrid(i,3));
end
fclose(id);
file_name = sprintf('V_vel_timestep_%d.txt',timestep);
id=fopen([savepath file_name],'w');
for i=1:length(Vgrid(:,1))
fprintf(id,'%f %f %f\n',Vgrid(i,1),Vgrid(i,2),Vgrid(i,3));
end
fclose(id);
file_name = sprintf('P_timestep_%d.txt',timestep);
id=fopen([savepath file_name],'w');
for i=1:length(Pgrid(:,1))
fprintf(id,'%f %f %f\n',Pgrid(i,1),Pgrid(i,2),Pgrid(i,3));
end
fclose(id);
%Saving complete and proceed to next time-step
end
end
function [Pgrid,Ugrid,Vgrid] = gridpointgenerator(nx,ny,deltax,deltay)
% Grid point generator
%Row by row, upward
%Pressure collocated grid points
Pgridx(1)=0;
Pgridy(1)=0;
for i=2:nx
Pgridx(i)=Pgridx(i-1)+deltax;
end
for i=2:ny
Pgridy(i)=Pgridy(i-1)+deltay;
end
count=1;
for i=1:ny
for j=1:nx
Pgridxp(count)=Pgridx(j);
Pgridyp(count)=Pgridy(i);
count=count+1;
end
end
%x vel collocated grid points
nx2=nx+1;
ugridx(1)=-(deltax/2);
ugridy(1)=0;
for i=2:nx2
ugridx(i)=ugridx(i-1)+deltax;
end
for i=2:ny
ugridy(i)=ugridy(i-1)+deltay;
end
count=1;
for i=1:ny
for j=1:nx2
ugridxp(count)=ugridx(j);
ugridyp(count)=ugridy(i);
count=count+1;
end
end
%y vel collocated grid points
ny2=ny+1;
vgridy(1)=-(deltay/2);
vgridx(1)=0;
for i=2:nx
vgridx(i)=vgridx(i-1)+deltax;
end
for i=2:ny2
vgridy(i)=vgridy(i-1)+deltay;
end
count=1;
for i=1:ny2
for j=1:nx
vgridxp(count)=vgridx(j);
vgridyp(count)=vgridy(i);
count=count+1;
end
end
Pgridxp=Pgridxp';
Pgridyp=Pgridyp';
ugridxp=ugridxp';
ugridyp=ugridyp';
vgridxp=vgridxp';
vgridyp=vgridyp';
figure
plot(Pgridxp,Pgridyp,'o','MarkerSize',5,'Markeredgecolor','k','markerfacecolor','k');
hold on
plot(ugridxp,ugridyp,'x','MarkerSize',5,'Markeredgecolor','b','markerfacecolor','b');
hold on
plot(vgridxp,vgridyp,'*','MarkerSize',5,'Markeredgecolor','g','markerfacecolor','g');
title('FDM Grid Points')
legend('Pressure Points','u vel points','v vel points');
Pgrid=[Pgridxp,Pgridyp];
Ugrid=[ugridxp,ugridyp];
Vgrid=[vgridxp,vgridyp];
end
