fed_batch_bioreactor_nbi.cpp
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1 /*
2  * This file is part of ACADO Toolkit.
3  *
4  * ACADO Toolkit -- A Toolkit for Automatic Control and Dynamic Optimization.
5  * Copyright (C) 2008-2014 by Boris Houska, Hans Joachim Ferreau,
6  * Milan Vukov, Rien Quirynen, KU Leuven.
7  * Developed within the Optimization in Engineering Center (OPTEC)
8  * under supervision of Moritz Diehl. All rights reserved.
9  *
10  * ACADO Toolkit is free software; you can redistribute it and/or
11  * modify it under the terms of the GNU Lesser General Public
12  * License as published by the Free Software Foundation; either
13  * version 3 of the License, or (at your option) any later version.
14  *
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19  *
20  * You should have received a copy of the GNU Lesser General Public
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22  * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
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24  */
25 
26 
47 #include "acado_optimal_control.hpp"
48 #include <acado_gnuplot.hpp>
49 
50 
51 int main( ){
52 
53  USING_NAMESPACE_ACADO
54 
55  // INTRODUCE FIXED PARAMETERS:
56  // ---------------------------
57  #define Csin 2.8
58 
59 
60  // INTRODUCE THE VARIABLES:
61  // -------------------------
62  DifferentialState x1,x2,x3,x4,x5;
63  IntermediateState mu,sigma,pif;
64  Control u ;
65  Parameter tf ;
66  DifferentialEquation f(0.0,tf) ;
67 
68 
69  // DEFINE A DIFFERENTIAL EQUATION:
70  // -------------------------------
71  mu = 0.125*x2/x4;
72  sigma = mu/0.135;
73  pif = (-384.0*mu*mu + 134.0*mu);
74 
75  f << dot(x1) == mu*x1;
76  f << dot(x2) == -sigma*x1 + u*Csin;
77  f << dot(x3) == pif*x1;
78  f << dot(x4) == u;
79  f << dot(x5) == 0.001*(u*u + 0.01*tf*tf);
80 
81 
82  // DEFINE AN OPTIMAL CONTROL PROBLEM:
83  // ----------------------------------
84  OCP ocp( 0.0, tf, 50 );
85  ocp.minimizeMayerTerm(0, 0.01*x5 -x3/tf ); // Solve productivity optimal problem (Note: - due to maximization, small regularisation term)
86  ocp.minimizeMayerTerm(1, 0.01*x5 -x3/(Csin*x4-x2)); // Solve yield optimal problem (Note: Csin = x2(t=0)/x4(t=0); - due to maximization, small regularisation term)
87 
88  ocp.subjectTo( f );
89 
90  ocp.subjectTo( AT_START, x1 == 0.1 );
91  ocp.subjectTo( AT_START, x2 == 14.0 );
92  ocp.subjectTo( AT_START, x3 == 0.0 );
93  ocp.subjectTo( AT_START, x4 == 5.0 );
94  ocp.subjectTo( AT_START, x5 == 0.0 );
95 
96  ocp.subjectTo( 0.0 <= x1 <= 15.0 );
97  ocp.subjectTo( 0.0 <= x2 <= 30.0 );
98  ocp.subjectTo( -0.1 <= x3 <= 1000.0 );
99  ocp.subjectTo( 5.0 <= x4 <= 20.0 );
100  ocp.subjectTo( 20.0 <= tf <= 40.0 );
101  ocp.subjectTo( 0.0 <= u <= 2.0 );
102 
103 
104  // DEFINE A MULTI-OBJECTIVE ALGORITHM AND SOLVE THE OCP:
105  // -----------------------------------------------------
106  MultiObjectiveAlgorithm algorithm(ocp);
107 
108  algorithm.set( PARETO_FRONT_DISCRETIZATION, 21 );
109  algorithm.set( PARETO_FRONT_GENERATION , PFG_NORMAL_BOUNDARY_INTERSECTION );
110  algorithm.set( HESSIAN_APPROXIMATION, EXACT_HESSIAN );
111  algorithm.set( KKT_TOLERANCE, 1e-7 );
112 
113  // Minimize individual objective function
114  algorithm.solveSingleObjective(0);
115 
116  // Minimize individual objective function
117  algorithm.solveSingleObjective(1);
118 
119  // Generate Pareto set
120  algorithm.set( KKT_TOLERANCE, 1e-6 );
121  algorithm.solve();
122 
123  algorithm.getWeights("fed_batch_bioreactor_nbi_weights.txt");
124  algorithm.getAllDifferentialStates("fed_batch_bioreactor_nbi_states.txt");
125  algorithm.getAllControls("fed_batch_bioreactor_nbi_controls.txt");
126  algorithm.getAllParameters("fed_batch_bioreactor_nbi_parameters.txt");
127 
128 
129  // VISUALIZE THE RESULTS IN A GNUPLOT WINDOW:
130  // ------------------------------------------
131  VariablesGrid paretoFront;
132  algorithm.getParetoFront( paretoFront );
133 
134  GnuplotWindow window1;
135  window1.addSubplot( paretoFront, "Pareto Front (yield versus productivity)", "-PRODUCTIVTY", "-YIELD", PM_POINTS );
136  window1.plot( );
137 
138 
139  // PRINT INFORMATION ABOUT THE ALGORITHM:
140  // --------------------------------------
141  algorithm.printInfo();
142 
143 
144  // SAVE INFORMATION:
145  // -----------------
146  paretoFront.print();
147 
148  return 0;
149 }
MatrixVariablesGrid::print
returnValue print(std::ostream &stream=std::cout, const char *const name=DEFAULT_LABEL, const char *const startString=DEFAULT_START_STRING, const char *const endString=DEFAULT_END_STRING, uint width=DEFAULT_WIDTH, uint precision=DEFAULT_PRECISION, const char *const colSeparator=DEFAULT_COL_SEPARATOR, const char *const rowSeparator=DEFAULT_ROW_SEPARATOR) const
Definition: matrix_variables_grid.cpp:695
MultiObjectiveAlgorithm::getWeights
DMatrix getWeights() const
PlotWindow::plot
virtual returnValue plot(PlotFrequency _frequency=PLOT_IN_ANY_CASE)
Definition: plot_window.cpp:166
acado_optimal_control.hpp
Csin
#define Csin
HESSIAN_APPROXIMATION
Definition: acado_types.hpp:376
USING_NAMESPACE_ACADO
#define USING_NAMESPACE_ACADO
Definition: acado_namespace_macros.hpp:59
VariablesGrid
Provides a time grid consisting of vector-valued optimization variables at each grid point...
Definition: variables_grid.hpp:56
MultiObjectiveAlgorithm::printInfo
returnValue printInfo()
PARETO_FRONT_GENERATION
Definition: acado_types.hpp:404
OCP::subjectTo
returnValue subjectTo(const DifferentialEquation &differentialEquation_)
Definition: ocp.cpp:153
OCP::minimizeMayerTerm
returnValue minimizeMayerTerm(const Expression &arg)
Definition: ocp.cpp:238
PlotWindow::addSubplot
returnValue addSubplot(PlotWindowSubplot &_subplot)
Definition: plot_window.cpp:276
Options::set
returnValue set(OptionsName name, int value)
Definition: options.cpp:126
MultiObjectiveAlgorithm::getAllControls
returnValue getAllControls(const char *fileName) const
EXACT_HESSIAN
Definition: acado_types.hpp:619
PARETO_FRONT_DISCRETIZATION
Definition: acado_types.hpp:403
PFG_NORMAL_BOUNDARY_INTERSECTION
Definition: acado_types.hpp:745
MultiObjectiveAlgorithm::getParetoFront
returnValue getParetoFront(VariablesGrid &paretoFront) const
PM_POINTS
Definition: acado_types.hpp:550
OCP
Data class for defining optimal control problems.
Definition: ocp.hpp:89
main
int main()
Definition: fed_batch_bioreactor_nbi.cpp:51
dot
Expression dot(const Expression &arg)
Definition: acado_syntax.cpp:98
KKT_TOLERANCE
Definition: acado_types.hpp:371
MultiObjectiveAlgorithm::solveSingleObjective
virtual returnValue solveSingleObjective(const int &number)
Definition: multi_objective_algorithm.cpp:142
MultiObjectiveAlgorithm
User-interface to formulate and solve optimal control problems with multiple objectives.
Definition: multi_objective_algorithm.hpp:54
MultiObjectiveAlgorithm::getAllDifferentialStates
returnValue getAllDifferentialStates(const char *fileName) const
GnuplotWindow
Provides an interface to Gnuplot for plotting algorithmic outputs.
Definition: gnuplot_window.hpp:58
AT_START
Definition: acado_types.hpp:732
MultiObjectiveAlgorithm::getAllParameters
returnValue getAllParameters(const char *fileName) const
acado_gnuplot.hpp
DifferentialEquation
Allows to setup and evaluate differential equations (ODEs and DAEs) based on SymbolicExpressions.
Definition: differential_equation.hpp:55

acado
Author(s): Milan Vukov, Rien Quirynen
autogenerated on Mon Jun 10 2019 12:34:34