I have based my solution off the example provided by Matlab - solving a third order differential equation.
My problem is that I have to solve the third order differential equation, y'''+3y''+2y'+y=4u, by using the ode23 solver and plot the step response. Here is what I have so far.
function dy = diffuy( t, y )
%Split uy into variables in equation
%y'''+3y''+2y'+y=4u
%Have to take third order equation and convert to 1st order
%y0 = y
%y1 = y0'
%y2 = y1'
%y3 = y2'
%y0' = y1
%y1' = y2
%y2' = y3
%y3' = y''' = -3*y2-2*y1-y0+4*u
%Assume that y(0)= 0, y'(0)=0, y''(0)=0, no initial conditions
u = @(t) heaviside(t);
dy = zeros(4,1);
dy(1) = y(2);
dy(2) = y(3);
dy(3) = y(4);
dy(4) = -3*y(3)-2*y(2)-y(1)+4*u(t);
end
In my main file, I have the code:
[T, Y]=ode23(@diffuy,[0 20],[0 0 0 0]);
figure(1)
plot(T,Y(:,1))
A=[0 1 0;0 0 1; -1 -2 -3]
B=[0;0;4]
C=[1 0 0]
D=[0]
sys4=ss(A,B,C,D)
figure(2)
step(sys4)
The problem I am having is that the step response produced from using the state-space representation commands in MATLAB do not match the step response produced by the ode23, so I assumed that I solved the differential equation incorrectly. Any tips or comments would be very helpful.
Step Response from ss commands:
Step Response from using ode23:
ss
and friends. Are you positive that you are entering the same system intoss
to check?ode23
,y(t=0)
is nonzero.