Multiple model iterative learning control for FES-based stroke rehabilitation
Multiple model iterative learning control for FES-based stroke rehabilitation
Functional electrical stimulation (FES) is an upper limb stroke rehabilitation technology that can enable patients to recover their lost movement by assisting functional task training. Unfortunately, current FES controllers cannot simultaneously satisfy the competing demands of high accuracy, robustness to modelling error and minimal set-up/identification time that are needed for clinical or home deployment. To address this, an estimation-based multiple model switched iterative learning control framework is proposed, combining the most successful adaptive and learning properties of existing FES controllers. A practical design procedure guaranteeing robust performance is developed, and initial experimental results are then presented to confirm efficacy of the approach.
Zhou, Junlin
4e4b04ca-2dc8-4a83-bee1-06e45e797e01
Freeman, Christopher
ccdd1272-cdc7-43fb-a1bb-b1ef0bdf5815
Holderbaum, William
f058d665-b418-463e-a42e-7fcb8382154c
Zhou, Junlin
4e4b04ca-2dc8-4a83-bee1-06e45e797e01
Freeman, Christopher
ccdd1272-cdc7-43fb-a1bb-b1ef0bdf5815
Holderbaum, William
f058d665-b418-463e-a42e-7fcb8382154c
Zhou, Junlin, Freeman, Christopher and Holderbaum, William
(2023)
Multiple model iterative learning control for FES-based stroke rehabilitation.
2023 American Control Conference, Hilton San Diego Bayfront Hotel, San Diego, United States.
31 May - 02 Jun 2023.
(In Press)
Record type:
Conference or Workshop Item
(Paper)
Abstract
Functional electrical stimulation (FES) is an upper limb stroke rehabilitation technology that can enable patients to recover their lost movement by assisting functional task training. Unfortunately, current FES controllers cannot simultaneously satisfy the competing demands of high accuracy, robustness to modelling error and minimal set-up/identification time that are needed for clinical or home deployment. To address this, an estimation-based multiple model switched iterative learning control framework is proposed, combining the most successful adaptive and learning properties of existing FES controllers. A practical design procedure guaranteeing robust performance is developed, and initial experimental results are then presented to confirm efficacy of the approach.
Text
Multiple Model iterative Learning Control for FES-based stroke rehabilitation
- Accepted Manuscript
Text
Multiple Model iterative Learning Control for FES-based stroke rehabilitation
- Accepted Manuscript
More information
Accepted/In Press date: 20 January 2023
Venue - Dates:
2023 American Control Conference, Hilton San Diego Bayfront Hotel, San Diego, United States, 2023-05-31 - 2023-06-02
Identifiers
Local EPrints ID: 482387
URI: http://eprints.soton.ac.uk/id/eprint/482387
PURE UUID: d11ddcab-9326-4807-a75d-621294e4a8fb
Catalogue record
Date deposited: 29 Sep 2023 16:38
Last modified: 15 Apr 2024 16:59
Export record
Contributors
Author:
Junlin Zhou
Author:
Christopher Freeman
Author:
William Holderbaum
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics