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How to solve ODE for varying input using ode23 ?

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Md Shahidul Alam
Md Shahidul Alam on 25 Aug 2016
Commented: Torsten on 26 Aug 2016
I'm trying to solve a RC circuit using ode23. For my case the input is varying with time. Here u is my input vector.
% function
function vdot = diff3(t,v)
u = [1 2 3 4 5] ;
vdot(1) = -40*v(1) + 20*v(2) + 20*u(t);
vdot(2) = 20*v(1) - 20*v(2) - v(3);
vdot(3) = 0.1*v(2) -1000*v(3);
vdot = [vdot(1);vdot(2);vdot(3)];
end
% main program
tspan = 1:5;
x0 = [0 0 0]; % initial conditions
[t,x] = ode23('diff3', tspan, x0);
tt = length(t);
for i = 1:tt
vo(i) = x(i,1) - x(i,2);
end
plot(t, vo)
title('Transient analysis of RLC')
xlabel('Time, s'), ylabel('Output voltage')
In case of fixed value of u = 5, there is no error. As my input is varying MATLAB is throwing some error. _
Attempted to access u(1); index must be a positive integer or logical.
Error in diff3 (line 9)
vdot(1) = -40*v(1) + 20*v(2) + 20*u(t);
Error in ode23 (line 256)
f(:,2) = feval(odeFcn,t+h*A(1),y+f*hB(:,1),odeArgs{:});
Error in rcckt (line 5)
[t,x] = ode23('diff3', tspan, x0);_
So how can I solve ODE for varying input? Any kind of suggestion will be really helpful. Thanks in advance!

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Accepted Answer

Torsten
Torsten on 25 Aug 2016
% function
function vdot = diff3(t,v)
u = [1 2 3 4 5] ;
tu = [1 2 3 4 5];
u_at_t = interp1(tu,u,t);
vdot(1) = -40*v(1) + 20*v(2) + 20*u_at_t;
vdot(2) = 20*v(1) - 20*v(2) - v(3);
vdot(3) = 0.1*v(2) -1000*v(3);
vdot = [vdot(1);vdot(2);vdot(3)];
end
Best wishes
Torsten.
  2 Comments
Md Shahidul Alam
Md Shahidul Alam on 25 Aug 2016
Thank you very much for your kind reply and solution. I changed it little bit to access different state input.
function vdot = diff3(t,v)
u = [1 2 3 4 5;
6 7 8 9 10;
11 12 13 14 15] ;
tu = [1 2 3 4 5];
u_at_t(1,:) = interp1(tu,u(1,:),t);
u_at_t(2,:) = interp1(tu,u(2,:),t);
u_at_t(3,:) = interp1(tu,u(3,:),t);
vdot(1) = -40*v(1) + 20*v(2) + 20*u_at_t(1,:);
vdot(2) = 20*v(1) - 20*v(2) - v(3) + u_at_t(2,:);
vdot(3) = 0.1*v(2) -1000*v(3) + u_at_t(3,:);
vdot = [vdot(1);vdot(2);vdot(3)];
end
Torsten
Torsten on 26 Aug 2016
Since interp1 only returns a scalar in each case,
function vdot = diff3(t,v)
u = [1 2 3 4 5;
6 7 8 9 10;
11 12 13 14 15] ;
tu = [1 2 3 4 5];
u_at_t(1) = interp1(tu,u(1,:),t);
u_at_t(2) = interp1(tu,u(2,:),t);
u_at_t(3) = interp1(tu,u(3,:),t);
vdot(1) = -40*v(1) + 20*v(2) + 20*u_at_t(1);
vdot(2) = 20*v(1) - 20*v(2) - v(3) + u_at_t(2);
vdot(3) = 0.1*v(2) -1000*v(3) + u_at_t(3);
vdot = [vdot(1);vdot(2);vdot(3)];
end
also works.
Best wishes
Torsten.

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