I don't know the cause of these jumps when finding a solution with a discontinuous reference function

2 vues (au cours des 30 derniers jours)
I have a simple function with error dynamics edot = -b0*e, which means that if I track a reference function Fref, the output F has state equation Fdot = -Frefdot - b0*(Fref - F). This can be solved using a discrete approximation, or using a two-state augmentation to get rid of the input derivative in the state equation. The problem occurs when Fref is discontinuous, e.g. if Fref = square(t).
MATLAB's ODE solvers are not intended to work with discontinuous functions, as previously pointed out in this question/answer. However, I'm working with a controller that provides discontinuous inputs, so I need an ok solution (i.e. not high fidelity, but reliably consistent) solution to this problem.
I tried to write a short, very simple 4th order Runge-Kutta solver so that I could solve the system above. The problem is that it still is inconsistent, and since it's a square wave and my RK4 is just arithmetic within the function at this point, that makes no sense to me (the behavior at time t = .5 should match that at time t = 1.5). Can someone please explain why my solver isn't consistent over the length of the square wave?
I attached my files (a script and two short functions). Running the solver_Analysis.m script shows results. The figure below shows the output. The reference is plotted, as is a discrete solution (to show what I expect), ode45 (to show why I can't use that; ode23 works slightly better but still with errors), and my RK4 solver.

Réponses (0)

Produits

Community Treasure Hunt

Find the treasures in MATLAB Central and discover how the community can help you!

Start Hunting!

Translated by