Direct Learning for Parameter-Varying Feedforward Control

Kon, Johan; van de Wijdeven, Jeroen; Bruijnen, Dennis; Toth, Roland; Heertjes, Marcel; Oomen, Tom

doi:10.1109/CDC49753.2023.10383877

Direct Learning for Parameter-Varying Feedforward Control

A Neural-Network Approach

Conference paper (2023)

Authors

Johan Kon Eindhoven University of Technology

Jeroen van de Wijdeven ASML

Dennis Bruijnen Philips Research

Roland Toth Eindhoven University of Technology, Institute for Computer Science and Control (SZTAKI)

Marcel Heertjes ASML, Eindhoven University of Technology

Tom Oomen Eindhoven University of Technology, Team Jan-Willem van Wingerden - Mechanical, Maritime and Materials Engineering

Research Group

Team Jan-Willem van Wingerden (Mechanical, Maritime and Materials Engineering) (TU Delft)

DOI: https://doi.org/10.1109/CDC49753.2023.10383877

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Published Date

2023

Language

English

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Faculty

Mechanical, Maritime and Materials Engineering

Department

Delft Center for Systems and Control

Research Group

Team Jan-Willem van Wingerden

Abstract

The performance of a feedforward controller is primarily determined by the extent to which it can capture the relevant dynamics of a system. The aim of this paper is to develop an input-output linear parameter-varying (LPV) feedforward parameterization and a corresponding data-driven estimation method in which the dependency of the coefficients on the scheduling signal are learned by a neural network. The use of a neural network enables the parameterization to compensate a wide class of constant relative degree LPV systems. Efficient optimization of the neural-network-based controller is achieved through a Levenberg-Marquardt approach with analytic gradients and a pseudolinear approach generalizing Sanathanan-Koerner to the LPV case. The performance of the developed feedforward learning method is validated in a simulation study of an LPV system showing excellent performance.

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