Disturbance observer-based repetitive control system with nonminimal state-space realization and experimental evaluation
Disturbance observer-based repetitive control system with nonminimal state-space realization and experimental evaluation
This brief develops a disturbance observer-based repetitive control system using a non-minimal state-space (NMSS) realization where all state variables correspond to the system's input and output variables and past values. Tracking a periodic reference signal or rejection of a periodic disturbance signal is achieved by including a disturbance observer to estimate an input disturbance containing the same frequency characteristics. This new approach differs from previously published designs because it separates the design procedure into two tasks: first, stabilization via state feedback control; second, independent incorporation of the periodic modes via estimation of the disturbance. Moreover, the new design naturally contains an anti-windup mechanism when the control signal reaches its maximum or minimum value. Results from the experimental evaluation are given, including a comparison against a design that constructs a minimal state controller using an observer. These results demonstrate that the new method can deliver significant performance improvement, with excellent disturbance rejection and reference tracking.
Anti-windup mechanism, disturbance observer, disturbance rejection, experimental validation, nonminimal state-space (NMSS) realization, repetitive control
961-968
Wang, Liuping
be52bfa9-e0c3-482c-947c-b0340e100eb0
Freeman, Christopher T.
ccdd1272-cdc7-43fb-a1bb-b1ef0bdf5815
Rogers, Eric
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Young, Peter
8c7c9373-2564-4536-aeea-145d0a004a66
1 March 2023
Wang, Liuping
be52bfa9-e0c3-482c-947c-b0340e100eb0
Freeman, Christopher T.
ccdd1272-cdc7-43fb-a1bb-b1ef0bdf5815
Rogers, Eric
611b1de0-c505-472e-a03f-c5294c63bb72
Young, Peter
8c7c9373-2564-4536-aeea-145d0a004a66
Wang, Liuping, Freeman, Christopher T., Rogers, Eric and Young, Peter
(2023)
Disturbance observer-based repetitive control system with nonminimal state-space realization and experimental evaluation.
IEEE Transactions on Control Systems Technology, 31 (2), .
(doi:10.1109/TCST.2022.3202299).
Abstract
This brief develops a disturbance observer-based repetitive control system using a non-minimal state-space (NMSS) realization where all state variables correspond to the system's input and output variables and past values. Tracking a periodic reference signal or rejection of a periodic disturbance signal is achieved by including a disturbance observer to estimate an input disturbance containing the same frequency characteristics. This new approach differs from previously published designs because it separates the design procedure into two tasks: first, stabilization via state feedback control; second, independent incorporation of the periodic modes via estimation of the disturbance. Moreover, the new design naturally contains an anti-windup mechanism when the control signal reaches its maximum or minimum value. Results from the experimental evaluation are given, including a comparison against a design that constructs a minimal state controller using an observer. These results demonstrate that the new method can deliver significant performance improvement, with excellent disturbance rejection and reference tracking.
Text
Disturbance observer-based Repitive control system with Nominimal state-space Relization and experimental Evaluation
- Accepted Manuscript
More information
Accepted/In Press date: 12 August 2022
e-pub ahead of print date: 20 September 2022
Published date: 1 March 2023
Keywords:
Anti-windup mechanism, disturbance observer, disturbance rejection, experimental validation, nonminimal state-space (NMSS) realization, repetitive control
Identifiers
Local EPrints ID: 474370
URI: http://eprints.soton.ac.uk/id/eprint/474370
ISSN: 1063-6536
PURE UUID: 993a5601-c729-4dab-b0e4-db26148cabb8
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Date deposited: 21 Feb 2023 17:33
Last modified: 11 Dec 2024 02:39
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Contributors
Author:
Liuping Wang
Author:
Christopher T. Freeman
Author:
Eric Rogers
Author:
Peter Young
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