Van der Pol Oscillator (JModelica): Difference between revisions

Latest revision as of 13:58, 19 January 2016

This page contains the source code to solve the Van der Pol Oscillator problem with JModelica. The automatic differentiation tool CasADI and the solver IPOPT were used to solve the problem.

Model file (VDP_Opt.mop)

//-------------------------------------------------------------------------
//Van der Pol Oscillator with direct collocation using JModelica
//(c) Madeleine Schroter
//--------------------------------------------------------------------------

optimization VDP_Opt(objectiveIntegrand = y^2+x^2+u^2, startTime = 0, finalTime = 20)

//The states
Real x(start=1, fixed=true); //position coordinate
Real y(start=0, fixed=true); 


//The control signal
input Real u; //damping of the oscillation

equation
der(y) = (1-x^2) * y - x +u;
der(x) = y;

constraint
u<=0.75;

end VDP_Opt;

Run file

#Import the function for transfering a model to CasADiInterface
from pyjmi import transfer_optimization_problem

op=transfer_optimization_problem("VDP_Opt", "VDP_Opt.mop")

res=op.optimize()

Revision as of 19:57, 12 January 2016 view source MadeleineSchroeter (talk \| contribs) 40 edits No edit summary ← Older edit		Latest revision as of 13:58, 19 January 2016 view source FelixMueller (talk \| contribs) 693 edits No edit summary
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	This page contains the source code to solve the Van der Pol Oscillator problem with JModelica. The automatic differentiation tool CasADI and the solver IPOPT were used to solve the problem.		This page contains the source code to solve the [[Van der Pol Oscillator]] problem with JModelica. The automatic differentiation tool CasADI and the solver IPOPT were used to solve the problem.

	Model file (VDP_Opt.mop)		Model file (VDP_Opt.mop)