LPV sequential loop closing for high-precision motion systems

Y.L.C. Broens; Hans Butler; Roland Tóth

doi:10.23919/ACC53348.2022.9867621

LPV sequential loop closing for high-precision motion systems

Y.L.C. Broens
, Hans Butler
, Roland Tóth

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

4 Citations (Scopus)

189 Downloads (Pure)

Abstract

Increasingly stringent throughput requirements in the industry necessitate the need for lightweight design of high-precision motion systems to allow for high accelerations, while still achieving accurate positioning of the moving-body. The presence of position dependent dynamics in such motion systems severely limits achievable position tracking performance using conventional sequential loop closing (SLC) control design strategies. This paper presents a novel extension of the conventional SLC design framework towards linear-parameter-varying systems, which allows to circumvent limitations that are introduced by position dependent effects in high-precision motion systems. Advantages of the proposed control design approach are demonstrated in simulation using a high-fidelity model of a moving-magnet planar actuator system, which exhibits position dependency in both actuation and sensing.

Original language	English
Title of host publication	2022 American Control Conference (ACC)
Publisher	Institute of Electrical and Electronics Engineers
Pages	3178-3183
Number of pages	6
ISBN (Electronic)	978-1-6654-5196-3
DOIs	https://doi.org/10.23919/ACC53348.2022.9867621
Publication status	Published - 5 Sept 2022
Event	2022 American Control Conference, ACC 2022 - Atlanta, United States Duration: 8 Jun 2022 → 10 Jun 2022 https://acc2022.a2c2.org/

Conference

Conference	2022 American Control Conference, ACC 2022
Abbreviated title	ACC 2022
Country/Territory	United States
City	Atlanta
Period	8/06/22 → 10/06/22
Internet address	https://acc2022.a2c2.org/

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10.23919/ACC53348.2022.9867621

Final_Author_VersionFinal author version , 2.68 MBLicence: CC BY-SA

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AU - Butler, Hans

AU - Tóth, Roland

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N2 - Increasingly stringent throughput requirements in the industry necessitate the need for lightweight design of high-precision motion systems to allow for high accelerations, while still achieving accurate positioning of the moving-body. The presence of position dependent dynamics in such motion systems severely limits achievable position tracking performance using conventional sequential loop closing (SLC) control design strategies. This paper presents a novel extension of the conventional SLC design framework towards linear-parameter-varying systems, which allows to circumvent limitations that are introduced by position dependent effects in high-precision motion systems. Advantages of the proposed control design approach are demonstrated in simulation using a high-fidelity model of a moving-magnet planar actuator system, which exhibits position dependency in both actuation and sensing.

AB - Increasingly stringent throughput requirements in the industry necessitate the need for lightweight design of high-precision motion systems to allow for high accelerations, while still achieving accurate positioning of the moving-body. The presence of position dependent dynamics in such motion systems severely limits achievable position tracking performance using conventional sequential loop closing (SLC) control design strategies. This paper presents a novel extension of the conventional SLC design framework towards linear-parameter-varying systems, which allows to circumvent limitations that are introduced by position dependent effects in high-precision motion systems. Advantages of the proposed control design approach are demonstrated in simulation using a high-fidelity model of a moving-magnet planar actuator system, which exhibits position dependency in both actuation and sensing.

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DO - 10.23919/ACC53348.2022.9867621

M3 - Conference contribution

SP - 3178

EP - 3183

BT - 2022 American Control Conference (ACC)

PB - Institute of Electrical and Electronics Engineers

T2 - 2022 American Control Conference, ACC 2022

Y2 - 8 June 2022 through 10 June 2022

ER -

LPV sequential loop closing for high-precision motion systems

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