Related to bvp4c matlab code
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Dear experts,
Anyone help me,
how to plot isotherm lines, contour plot, surface plot using matlab bvp4c.
suggests any sample codes or any ideas.
Thank you.
this is our code
function hybrid(solver)
if nargin < 1
solver = 'bvp4c';
end
bvpsolver = fcnchk(solver);
xlow=0;
g1=-1;
g2=1;
g3=0.5;
g4=0.5;
global St rad m
St=0.2;
infinity=01;
maxinfinity=15;
solinit=bvpinit(linspace(0,infinity,1001),[St g1 1 g2 0 1 g3 1 g4]);
sol = bvpsolver(@ode,@bc,solinit);
x = sol.x;
y = sol.y;
fprintf('\n');
fprintf('At eta= %g \t %10.8f \t %10.8f \t %10.8f %10.8f.\n',xlow,y(2,1),y(4,1),y(7,1),y(9,1))
for Bnew = infinity:01:maxinfinity
solinit = bvpxtend(sol,Bnew);
sol = bvpsolver(@ode,@bc,solinit);
x = sol.x;
y = sol.y;
fprintf('At eta= %g \t %10.8f \t %10.8f \t %10.8f %10.8f.\n',Bnew,y(2,1),y(4,1),y(7,1),y(9,1))
end
fprintf('%10.8f \t %10.8f \t %10.8f \t %10.8f.\n',y(2,1),y(4,1),y(7,1),y(9,1))
plot(x,y(6,:),'-','Linewidth',1.5)
% hold on
%Cf=rad*(1+rad)^m*((0.32906655)^2+(-1.12865255)^2)^(1/2)
%Nu=-rad*(1+rad)^m*y(7);
%Sh=-rad*(1+rad)^m*y(9)
%Sn=-rad*(1+rad)^m*y(11)
function dydx=ode(x,y)
% rhos1 = 2810; Cps1 = 960; ks1 = 173; Pi1 = 0.1; ss1 = 26.77*(10^6); %AA7075
% rhos2 = 2720; Cps2 = 893.2; ks2 = 222; Pi2 = 0.3; ss2 = 34.83*(10^6); %AA7072
% rhof = 792; Cpf = 2545; kf = 0.2035; sf = 0.5*(10^(-6)); %(Methonal)
Np=2;
alpha=0.15;
eps=0.45;
Re=1;
Pr=1.5;
rad=0.2;
m=1.1;
n=0.1;
Sc=01;
Beta=1;
B=1;
Ha=0.2;
Ec=0.1;
Del=0.01;
h=0.5;
Rp=1.5;
% knf = kf*(ks1+(Np-1)*kf-(Np-1)*Pi1*(kf-ks1))/(ks1+(Np-1)*kf+Pi1*(kf-ks1));
% K =(ks2+(Np-1)*knf+Pi2*(knf-ks2)) /(ks2+(Np-1)*knf-(Np-1)*Pi2*(knf-ks2));%khnf/kf
%
% snf = sf*(ss1+2*sf-2*Pi1*(sf-ss1))/(ss1+2*sf+Pi1*(sf-ss1));
% S = (ss2+2*snf-2*Pi2*(snf-ss2))/(ss2+2*snf+Pi2*(snf-ss2));%shnf/sf
%
% Rh=(1-Pi2)*((1-Pi1)+Pi1*((rhos1*Cps1)/(rhof*Cpf)))+Pi2*((rhos2*Cps2)/(rhof*Cpf));
% Mu=1/((1-Pi1)^(2.5)*(1-Pi2)^(2.5));
% D=1.8;
% RaggRp=3.34;
% Pmax=0.605;
% Pint=(RaggRp)^(D-3);
% Pagg=Pi/Pint;
% rhoagg=(1-Pint)*rhof+Pint*rhos;
% Mu=(1/(Pagg/Pmax))^(-2.5*Pmax);
% Rh=(1-Pagg)+((Pagg*rhoagg)/rhof);
% rhoCpagg=(1-Pint)*(rhof*Cpf)+Pint*rhos*Cps;
% kagg=(kf/4)*((3*Pint-1)*(ks/kf)+(3*(1-Pint)-1)+(((3*Pint-1)*(ks/kf)+(3*(1-Pint)-1))^2+(8*ks/kf))^0.5);
% RhCp=(1-Pagg)+Pagg*(rhoCpagg/(rhof*Cpf));
% K=(kagg+2*kf+2*Pagg*(kagg-kf))/(kagg+2*kf-Pagg*(kagg-kf));
% S=1+(((3*(ss/sf)-1)*Pagg)/((ss/sf)+2)*((ss/sf)-1)*Pagg);
rhos = 2810; Cps = 960; ks = 173; Pi = 0.1; ss = 26.77*(10^6); %AA7075
rhof = 792; Cpf = 2545; kf = 0.2035; sf = 0.5*(10^(-6)); %(Methonal)
Mu=1+2.5*Del+4.5*(1/((h/Rp)*(2+(h/Rp))*(1+(h/Rp))^2));
Rh=(1-Del)+Del*(rhos/rhof);
RhCp=(1-Del)+Del*(rhos*Cps/rhof*Cpf);
K=(ks+2*kf-2*Del*(kf-ks))/(ks+2*kf+Del*(kf-ks));
S=(ss+2*sf-2*Del*(sf-ss))/(ss+2*sf+Del*(sf-ss));
dydx=[y(2)
Rh*(y(1)^2-y(3)^2+m*eps*(x+alpha)*y(1)*y(2)+y(5)*y(2))-(B/Re^2)+S*Ha*y(1)/Mu*Re^((1-n)/(1+n))*(1+rad)^(2*m)*(1+(1/Beta))
y(4)
Rh*(2*y(1)*y(3)+y(5)*y(4)+m*eps*(x+alpha)*y(1)*y(4))+S*Ha*y(3)/Mu*Re^((1-n)/(1+n))*(1+rad)^(2*m)*(1+(1/Beta))
-2*y(1)-m*eps*(x+alpha)*y(2)
y(7)
(y(1)*y(7)*m*eps*(x+alpha)*Pr+Pr*y(5)*y(7)+Pr*(S*RhCp)*Ha*Ec*(y(1)^2+y(3)^2))/(K*RhCp)*Re^((1-n)/(1+n))*(1+rad)^(2*m)
y(9)
(Sc*y(1)*y(9)*m*eps*(x+alpha)+Sc*y(5)*y(9))/(Mu*Re^((1-n)/(1+n))*(1+rad)^(2*m))
];
end
function res=bc(y0,yinf)
res=[y0(1)-St
y0(3)-1
y0(5)
y0(6)-1
y0(8)-1
yinf(1)
yinf(3)
yinf(6)
yinf(8)
];
end
end
Respuestas (1)
Syed Sohaib Zafar
el 5 de Oct. de 2023
0 votos
I think You need these kind of graphs.
To plot such graphs, use the command "contourf".
Find more help from the link below.
https://www.mathworks.com/help/matlab/ref/contourf.html
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