Multiple-model iterative learning control with application to stroke rehabilitation
Multiple-model iterative learning control with application to stroke rehabilitation
Model-based iterative learning control (ILC) algorithms achieve high accuracy but often exhibit poor robustness to model uncertainty, causing divergence and long-term instability as the number of trials increases. To address this, an estimation-based multiple-model switched ILC (EMMILC) approach is developed based on novel theorem results which guarantee stability if the true plant lies within a uncertainty space defined by the designer. Using gap metric analysis, EMMILC eliminates restrictive assumptions on the uncertainty structure assumed in existing multiple-model ILC methods. Our design framework minimises computational load while maximising tracking accuracy. Applied to a common rehabilitation scenario, EMMILC outperforms the standard ILC approaches that have been previously employed in this setting. This is confirmed by experimental tests with four participants where performance increased by 28%. EMMILC is the first model-based ILC framework that can guarantee high performance while not requiring any model identification or tuning, and paves the way for effective, home-based rehabilitation systems.
106134
Zhou, Junlin
4e4b04ca-2dc8-4a83-bee1-06e45e797e01
Freeman, Christopher T.
ccdd1272-cdc7-43fb-a1bb-b1ef0bdf5815
Holderbaum, William
f058d665-b418-463e-a42e-7fcb8382154c
29 October 2024
Zhou, Junlin
4e4b04ca-2dc8-4a83-bee1-06e45e797e01
Freeman, Christopher T.
ccdd1272-cdc7-43fb-a1bb-b1ef0bdf5815
Holderbaum, William
f058d665-b418-463e-a42e-7fcb8382154c
Zhou, Junlin, Freeman, Christopher T. and Holderbaum, William
(2024)
Multiple-model iterative learning control with application to stroke rehabilitation.
Control Engineering Practice, 154, .
(doi:10.1016/j.conengprac.2024.106134).
Abstract
Model-based iterative learning control (ILC) algorithms achieve high accuracy but often exhibit poor robustness to model uncertainty, causing divergence and long-term instability as the number of trials increases. To address this, an estimation-based multiple-model switched ILC (EMMILC) approach is developed based on novel theorem results which guarantee stability if the true plant lies within a uncertainty space defined by the designer. Using gap metric analysis, EMMILC eliminates restrictive assumptions on the uncertainty structure assumed in existing multiple-model ILC methods. Our design framework minimises computational load while maximising tracking accuracy. Applied to a common rehabilitation scenario, EMMILC outperforms the standard ILC approaches that have been previously employed in this setting. This is confirmed by experimental tests with four participants where performance increased by 28%. EMMILC is the first model-based ILC framework that can guarantee high performance while not requiring any model identification or tuning, and paves the way for effective, home-based rehabilitation systems.
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Accepted/In Press date: 10 October 2024
e-pub ahead of print date: 29 October 2024
Published date: 29 October 2024
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Local EPrints ID: 497204
URI: http://eprints.soton.ac.uk/id/eprint/497204
ISSN: 0967-0661
PURE UUID: d94b9d00-1b5c-4984-a180-a931b12ed365
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Date deposited: 15 Jan 2025 18:10
Last modified: 22 Aug 2025 01:50
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Author:
Junlin Zhou
Author:
Christopher T. Freeman
Author:
William Holderbaum
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