Second order ODE - BVP

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sko
sko 2021년 2월 1일
댓글: sko 2021년 2월 2일
Hi,
I am trying to obtain the solution of the following second order ODE but I struggle.
and on the interval [0, 0.5]. It is my understanding that 1) transoformation to the system of first order ODE and a Matlab bvp4c solver should be used. I wrote therefore the code:
function bvp5
xlow=0; xhigh=0.5;
solinit = bvpinit(linspace(xlow,xhigh,10),[0 1]);
sol = bvp4c(@bvp5ode,@bvp5bc,solinit);
xint = linspace(xlow,xhigh);
Sxint = deval(sol,xint);
plot(xint,Sxint(1,:))
% -----------------------------------------------
function dydx = bvp5ode(x,y)
dydx = [ y(2) 0.64*y(1)-(2/x)*y(2) ];
% -----------------------------------------------
function res = bvp5bc(ya,yb)
res = [ ya(1)-0.2 yb(2) ];
I obtain the folelowing error: Unable to solve the collocation equations -- a
singular Jacobian encountered.
1) How to form a guess ? I dont have any idea ...
2) What is the problem with my equation or my code?
Best wishes,

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Alan Stevens
Alan Stevens 2021년 2월 1일
I used an alternative method that makes use of Matlab's fzero function. You can also see one way of avoiding the problem at x = 0:
xlow=0; xhigh=0.5;
xspan = [xlow xhigh];
dydx0 = 0;
y0 = 0; % Initial guess for y(x=0)
% Use fzero to get value of y0 that makes y(x=0.5) = 0.1;
y0 = fzero(@(y0) y0val(y0, xspan), y0);
disp(['y(x=0) = ' num2str(y0)])
% Now use ode45 to integrate from x=0 to x=0.5 with good starting value
% for y(x=0)
Y0 = [y0 0];
[x, Y] = ode45(@odefn, xspan, Y0);
plot(x,Y(:,1)),grid
xlabel('x'),ylabel('y')
function Z = y0val(y0, xspan)
Y0 = [y0, 0];
[~, Y] = ode45(@odefn, xspan, Y0);
yend = Y(end,1);
Z = yend - 0.1;
end
function dYdx = odefn(x, Y)
y = Y(1); dydx = Y(2);
d2ydx2 = 0.64*y;
if dydx>0
d2ydx2 = d2ydx2 - (2/x)*dydx;
end
dYdx = [dydx;
d2ydx2];
end
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Alan Stevens
Alan Stevens 2021년 2월 2일
편집: Alan Stevens 2021년 2월 2일
I think the problem with using bpv4c is that it expects values of y(x=0) and y(x=0.5), but you have y'(x=0), not y(x=0). I'm not very familiar with bvp4c (I rarely use it), so I can't really help you further with it.
It's true that the shooting method requires a reasonable initial guess. Presumably your actual problem is much more complicated if the method is no use to you.
(NB In your analytical solution you have k = 6.4 and D = 0.1. This doesn't result in k/D = 0.64 !!!)
sko
sko 2021년 2월 2일
OMG
:)
Nothing else to add!
I obtain the good agreement with the analytical solution. Many Many thanks!

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추가 답변 (1개)

Alan Stevens
Alan Stevens 2021년 2월 1일
편집: Alan Stevens 2021년 2월 1일
You start at xlow = 0, but your function bvp5ode has an x in the denominator. bvp4c doesn't like it when this is zero! If you set xlow = 0.001, say, then it runs.
  댓글 수: 1
sko
sko 2021년 2월 1일
Hi, Thank you very much for your answer. It shows no error indeed. However, as you may have noticed, my equation is some sort of stationary diffusion-reaction equation, therefore, I should be able to have x=0 (surface of particle). Another important question is the guess function. Could you comment on this subject?
Thank you in advance

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