Receding Horizon Optimal Control of Wiener Systems by Application of an Asymmetric Cost Function

Daniel Alberer; Harald Kirchsteiger; Luigi del Re; Hans Joachim Ferreau; Moritz Diehl

Receding Horizon Optimal Control of Wiener Systems by Application of an Asymmetric Cost Function

Daniel Alberer, Harald Kirchsteiger, Luigi del Re, Hans Joachim Ferreau, Moritz Diehl

Institute of Design and Control of Mechatronical Systems

Research output: Chapter in Book/Report/Conference proceeding › Conference proceedings › peer-review

Abstract

Wiener models are an important class of nonlinear systems which well approximate many applications. Real time optimal control of Wiener models, for instance in the form of receding horizon optimal control, can be done using the nonlinear setup and corresponding nonlinear optimization tools. However, as this paper shows, under rather mild conditions on the static nonlinearity, it is possible to reformulate the optimal control problem as a linear problem with an asymmetric cost function, whose solution can be computed using a slack variable extension of the initial quadratic problem with a small additional computational cost. This paper shows the approach and the achievable performance at the example of the emission control of a large gas engine used in the U.S. pipeline network.

Original language	English
Title of host publication	Proceedings of the CAO 2009
Number of pages	6
Volume	7
Publication status	Published - 2009

Publication series

Name	Control Applications of Optimization

Fields of science

202 Electrical Engineering, Electronics, Information Engineering
202027 Mechatronics
202034 Control engineering
203027 Internal combustion engines
206001 Biomedical engineering
206002 Electro-medical engineering
207109 Pollutant emission

Cite this

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title = "Receding Horizon Optimal Control of Wiener Systems by Application of an Asymmetric Cost Function",

abstract = "Wiener models are an important class of nonlinear systems which well approximate many applications. Real time optimal control of Wiener models, for instance in the form of receding horizon optimal control, can be done using the nonlinear setup and corresponding nonlinear optimization tools. However, as this paper shows, under rather mild conditions on the static nonlinearity, it is possible to reformulate the optimal control problem as a linear problem with an asymmetric cost function, whose solution can be computed using a slack variable extension of the initial quadratic problem with a small additional computational cost. This paper shows the approach and the achievable performance at the example of the emission control of a large gas engine used in the U.S. pipeline network.",

author = "Daniel Alberer and Harald Kirchsteiger and {del Re}, Luigi and Ferreau, {Hans Joachim} and Moritz Diehl",

year = "2009",

language = "English",

volume = "7",

series = "Control Applications of Optimization",

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T1 - Receding Horizon Optimal Control of Wiener Systems by Application of an Asymmetric Cost Function

AU - Alberer, Daniel

AU - Kirchsteiger, Harald

AU - del Re, Luigi

AU - Ferreau, Hans Joachim

AU - Diehl, Moritz

PY - 2009

Y1 - 2009

N2 - Wiener models are an important class of nonlinear systems which well approximate many applications. Real time optimal control of Wiener models, for instance in the form of receding horizon optimal control, can be done using the nonlinear setup and corresponding nonlinear optimization tools. However, as this paper shows, under rather mild conditions on the static nonlinearity, it is possible to reformulate the optimal control problem as a linear problem with an asymmetric cost function, whose solution can be computed using a slack variable extension of the initial quadratic problem with a small additional computational cost. This paper shows the approach and the achievable performance at the example of the emission control of a large gas engine used in the U.S. pipeline network.

AB - Wiener models are an important class of nonlinear systems which well approximate many applications. Real time optimal control of Wiener models, for instance in the form of receding horizon optimal control, can be done using the nonlinear setup and corresponding nonlinear optimization tools. However, as this paper shows, under rather mild conditions on the static nonlinearity, it is possible to reformulate the optimal control problem as a linear problem with an asymmetric cost function, whose solution can be computed using a slack variable extension of the initial quadratic problem with a small additional computational cost. This paper shows the approach and the achievable performance at the example of the emission control of a large gas engine used in the U.S. pipeline network.

M3 - Conference proceedings

VL - 7

T3 - Control Applications of Optimization

BT - Proceedings of the CAO 2009

ER -