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Main Authors: Zhang, Fan, Chen, Jinfeng, Hu, Yu, Gao, Zhiqiang, Lv, Ge, Lin, Qin
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2404.10240
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author Zhang, Fan
Chen, Jinfeng
Hu, Yu
Gao, Zhiqiang
Lv, Ge
Lin, Qin
author_facet Zhang, Fan
Chen, Jinfeng
Hu, Yu
Gao, Zhiqiang
Lv, Ge
Lin, Qin
contents Model uncertainty presents significant challenges in vibration suppression of multi-inertia systems, as these systems often rely on inaccurate nominal mathematical models due to system identification errors or unmodeled dynamics. An observer, such as an extended state observer (ESO), can estimate the discrepancy between the inaccurate nominal model and the true model, thus improving control performance via disturbance rejection. The conventional observer design is memoryless in the sense that once its estimated disturbance is obtained and sent to the controller, the datum is discarded. In this research, we propose a seamless integration of ESO and machine learning. On one hand, the machine learning model attempts to model the disturbance. With the assistance of prior information about the disturbance, the observer is expected to achieve faster convergence in disturbance estimation. On the other hand, machine learning benefits from an additional assurance layer provided by the ESO, as any imperfections in the machine learning model can be compensated for by the ESO. We validated the effectiveness of this novel learning-for-control paradigm through simulation and physical tests on two-inertial motion control systems used for vibration studies.
format Preprint
id arxiv_https___arxiv_org_abs_2404_10240
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Disturbance Rejection-Guarded Learning for Vibration Suppression of Two-Inertia Systems
Zhang, Fan
Chen, Jinfeng
Hu, Yu
Gao, Zhiqiang
Lv, Ge
Lin, Qin
Systems and Control
Model uncertainty presents significant challenges in vibration suppression of multi-inertia systems, as these systems often rely on inaccurate nominal mathematical models due to system identification errors or unmodeled dynamics. An observer, such as an extended state observer (ESO), can estimate the discrepancy between the inaccurate nominal model and the true model, thus improving control performance via disturbance rejection. The conventional observer design is memoryless in the sense that once its estimated disturbance is obtained and sent to the controller, the datum is discarded. In this research, we propose a seamless integration of ESO and machine learning. On one hand, the machine learning model attempts to model the disturbance. With the assistance of prior information about the disturbance, the observer is expected to achieve faster convergence in disturbance estimation. On the other hand, machine learning benefits from an additional assurance layer provided by the ESO, as any imperfections in the machine learning model can be compensated for by the ESO. We validated the effectiveness of this novel learning-for-control paradigm through simulation and physical tests on two-inertial motion control systems used for vibration studies.
title Disturbance Rejection-Guarded Learning for Vibration Suppression of Two-Inertia Systems
topic Systems and Control
url https://arxiv.org/abs/2404.10240