A robustified Newton based Extremum Seeking for Engine Optimization

Martin Großbichler; Roman Schmied; Philipp Polterauer; Harald Siegfried Waschl; Luigi Del Re

A robustified Newton based Extremum Seeking for Engine Optimization

Martin Großbichler, Roman Schmied, Philipp Polterauer, Harald Siegfried Waschl, Luigi Del Re

Institute of Design and Control of Mechatronical Systems

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

Abstract

Extremum seeking (ES) is a well known approach for online optimization of control parameters, e.g. in engine control. While the basic idea of ES is rather straightforward,in practice its application suffers from the problems related to determine the optimum numerically using measurements corrupted by noise. In addition, nonlinearities of the system under scrutiny, e.g. engines, can lead to a non convex objective function and thus to numerical problems. The purpose of this paper is to introduce a simply implementable extension to Newton based methods to improve the robustness of the convergence under real world conditions and to test it on a production Diesel engine. The extension is based on the regularization idea, and does not introduce significant additional tuning and setup effort. The results clearly show the improvements with respect to standard gradient and Newton based ES algorithms. The key advantage of this method is to provide convergence properties independently from the operating point and without re-tuning.

Original language	English
Title of host publication	American Control Conference 2016 (ACC16)
Number of pages	6
Publication status	Published - Jul 2016

Fields of science

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

JKU Focus areas

Mechatronics and Information Processing

Cite this

@inproceedings{54f161ffe60a44f0b86fea11787246e6,

title = "A robustified Newton based Extremum Seeking for Engine Optimization",

abstract = "Extremum seeking (ES) is a well known approach for online optimization of control parameters, e.g. in engine control. While the basic idea of ES is rather straightforward,in practice its application suffers from the problems related to determine the optimum numerically using measurements corrupted by noise. In addition, nonlinearities of the system under scrutiny, e.g. engines, can lead to a non convex objective function and thus to numerical problems. The purpose of this paper is to introduce a simply implementable extension to Newton based methods to improve the robustness of the convergence under real world conditions and to test it on a production Diesel engine. The extension is based on the regularization idea, and does not introduce significant additional tuning and setup effort. The results clearly show the improvements with respect to standard gradient and Newton based ES algorithms. The key advantage of this method is to provide convergence properties independently from the operating point and without re-tuning.",

author = "Martin Gro{\ss}bichler and Roman Schmied and Philipp Polterauer and Waschl, {Harald Siegfried} and {Del Re}, Luigi",

year = "2016",

month = jul,

language = "English",

booktitle = "American Control Conference 2016 (ACC16)",

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T1 - A robustified Newton based Extremum Seeking for Engine Optimization

AU - Großbichler, Martin

AU - Schmied, Roman

AU - Polterauer, Philipp

AU - Waschl, Harald Siegfried

AU - Del Re, Luigi

PY - 2016/7

Y1 - 2016/7

N2 - Extremum seeking (ES) is a well known approach for online optimization of control parameters, e.g. in engine control. While the basic idea of ES is rather straightforward,in practice its application suffers from the problems related to determine the optimum numerically using measurements corrupted by noise. In addition, nonlinearities of the system under scrutiny, e.g. engines, can lead to a non convex objective function and thus to numerical problems. The purpose of this paper is to introduce a simply implementable extension to Newton based methods to improve the robustness of the convergence under real world conditions and to test it on a production Diesel engine. The extension is based on the regularization idea, and does not introduce significant additional tuning and setup effort. The results clearly show the improvements with respect to standard gradient and Newton based ES algorithms. The key advantage of this method is to provide convergence properties independently from the operating point and without re-tuning.

AB - Extremum seeking (ES) is a well known approach for online optimization of control parameters, e.g. in engine control. While the basic idea of ES is rather straightforward,in practice its application suffers from the problems related to determine the optimum numerically using measurements corrupted by noise. In addition, nonlinearities of the system under scrutiny, e.g. engines, can lead to a non convex objective function and thus to numerical problems. The purpose of this paper is to introduce a simply implementable extension to Newton based methods to improve the robustness of the convergence under real world conditions and to test it on a production Diesel engine. The extension is based on the regularization idea, and does not introduce significant additional tuning and setup effort. The results clearly show the improvements with respect to standard gradient and Newton based ES algorithms. The key advantage of this method is to provide convergence properties independently from the operating point and without re-tuning.

M3 - Conference proceedings

BT - American Control Conference 2016 (ACC16)

ER -