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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: enter image description here

Step Response from using ode23:

enter image description here

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  • Your solution seems reasonable, however I'm unfamiliar with ss and friends. Are you positive that you are entering the same system into ss to check? Aug 30, 2015 at 0:23
  • I am pretty sure that I entered the same system. I guess I'll just have to wait for someone who is familiar with state-space. Thanks anyways :) Aug 30, 2015 at 0:30
  • It seems you're right:) Aug 30, 2015 at 0:48
  • Are you intentionally using nonzero initial conditions, contradicting your comments in the code? Your third parameter into ode23, y(t=0) is nonzero. Aug 30, 2015 at 0:53
  • Thanks for the correction! However, I am still not getting the step responses to match. I am not sure if it is because the input, u, I used is the heaviside function, which I have run into problems in the past because of it, or it is something else. Aug 30, 2015 at 1:02

1 Answer 1

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I'm not sure how the linked question got the correct answer because you're actually solving a fourth-order equation using their methodology. The right hand-side vector given to the ODE suite should only have n entries for an n-order problem.

In your case, the change of variables

Change of variables matrix

results in the third order system

Third order system equation

with the initial conditions

Initial conditions equation.

Changing diffuy to

function dy = diffuy( t, y )        
    dy =  zeros(3,1);
    dy(1) = y(2);
    dy(2) = y(3);
    dy(3) = -3*y(3)-2*y(2)-y(1)+4*u(t);
end

gives a solution that matches the state-space model.

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  • 1
    o wow, I guess you always have to cross-check answers even though they get up-voted. Thanks a lot, this was helpful. Aug 30, 2015 at 1:15

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