Solving a system of ODE

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Esraa Abdelkhaleq
Esraa Abdelkhaleq il 14 Feb 2017
Commentato: Star Strider il 15 Feb 2017
Hello,
How can I solve a system of two ODE's as follows,
dNcdt= Nc(t)*Kgr- dc*Nc(t)*Ni(t)
dNidt= ai*Nc(t) - di*Ni(t)
To obtain Nc(t) and Ni(t).
Thanks in advance.

Risposta accettata

Star Strider
Star Strider il 14 Feb 2017
It is easier to let the Symbolic Math Toolbox do the algebra:
syms ai dc di Kgr Nc(t) Ni(t) t Y
Eq1 = diff(Nc) == Nc(t)*Kgr- dc*Nc(t)*Ni(t);
Eq2 = diff(Ni) == ai*Nc(t) - di*Ni(t);
[odesys, vrs] = odeToVectorField(Eq1, Eq2);
odefcn = matlabFunction(odesys, 'Vars',[t Y ai dc di Kgr])
odefcn =
function_handle with value:
@(t,Y,ai,dc,di,Kgr)[ai.*Y(2)-di.*Y(1);Kgr.*Y(2)-dc.*Y(1).*Y(2)]
The rest should be relatively straightforward for you to complete. To solve it numerically, begin with ode45, and if your equation turns out to be ‘stiff’ because of a wide variation in parameter magnitudes, and ode45 has problems, use ode15s or one of the other stiff solvers appropriate to your system.
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Esraa Abdelkhaleq
Esraa Abdelkhaleq il 15 Feb 2017
OK. Thanks a lot for your help.
Star Strider
Star Strider il 15 Feb 2017
My pleasure.
Out doing stuff for 3 hours (life intrudes) so just got back to this topic.
This code:
syms ai dc di fc fch fi fih Ke Kgr Nc(t) Ni(t) Rc Rch Ri Rih t Y Nc0 Nch0 Nih0 Ni0 qpl(t)
Eq1 = diff(Nc) == Nc(t)*Kgr- dc*Nc(t)*Ni(t);
Eq2 = diff(Ni) == ai*Nc(t) - di*Ni(t);
Eq3 = diff(qpl) == fc*Rc*Nc(t)+ fi*Ri*Ni(t)+fch*Rch*Nch0+ fih*Rih*Nih0-Ke*qpl(t) ;
[odesys, vrs] = odeToVectorField(Eq1, Eq2, Eq3)
odefcn = matlabFunction(odesys, 'Vars',[t Y ai dc di fc fch fi fih Ke Kgr Nc0 Nch0 Nih0 Ni0 Rc Rch Ri Rih])
produces:
odesys =
ai*Y[2] - di*Y[1]
Kgr*Y[2] - dc*Y[1]*Y[2]
Nch0*Rch*fch - Ke*Y[3] + Nih0*Rih*fih + Rc*fc*Y[2] + Ri*fi*Y[1]
vrs =
Ni
Nc
qpl
odefcn = @(t,Y,ai,dc,di,fc,fch,fi,fih,Ke,Kgr,Nc0,Nch0,Nih0,Ni0,Rc,Rch,Ri,Rih) [ai.*Y(2)-di.*Y(1);Kgr.*Y(2)-dc.*Y(1).*Y(2);-Ke.*Y(3)+Nch0.*Rch.*fch+Nih0.*Rih.*fih+Rc.*fc.*Y(2)+Ri.*fi.*Y(1)];
The ‘vrs’ output you can interpret as:
Y(1) = Ni
Y(2) = Nc
Y(3) = qpl
You have to supply all the values for the parameters, so you can then integrate it with ode45 or ode15s (or other solver, depending on your requirements).

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