Filter-based immersion and invariance adaptive control

被引：0

作者：

Chen W. ^{[1
]}

Hu J. ^{[1
]}

Yao J.-Y. ^{[1
]}

Nie W.-R. ^{[1
]}

Zhou H.-B. ^{[2
]}

机构：

[1] College of Mechanical Engineering, Nanjing University of Science and Technology, Nanjing

[2] State Key Laboratory of High-Performance Complex Manufacturing, Central South University, Changsha

来源：

Kongzhi yu Juece/Control and Decision | 2024年 / 39卷 / 01期

关键词：

adaptive control; asymptotic stability; disturbance observer; immersion and invariance; mechatronic servo system; states filters;

D O I：

10.13195/j.kzyjc.2022.0370

中图分类号：

学科分类号：

摘要：

This paper proposes a filter-based immersion and invariance adaptive controller for mechatronics servo systems with parameter uncertainties, unmodeled dynamics and time-varying disturbance. First, a filter of the system states and regression function is constructed, and a parameter estimator is built based on the filtered auxiliary variables. Next, the auxiliary function in the parameter estimator needs to be designed according to the immersion and invariance theory to ensure the convergence of the parameter estimation error. Moreover, this paper proposes a disturbance observer to further reduce the impact of lumped disturbances on the closed-loop performance of the system. This disturbance observer, which is simple in structure, can ensure the asymptotic stability of the estimation error. The Lyapunov theory is used to prove the stability of the parameter estimator, the disturbance observer, and the closed-loop system, respectively, thus can efficiently compensate for unmodelled dynamics and external disturbances in the system. The simulation and experimental results demonstrate the effectiveness of the proposed adaptive method and the disturbance observer. © 2024 Northeast University. All rights reserved.

引用

页码：151 / 160

页数：9

共 28 条

[1] Cao W, Qiao J J, Sun M., Backstepping control of disturbance estimation and compensation for permanent magnet linear motor, Control and Decision, 35, 6, pp. 1409-1414, (2020)
[2] Sun L, Ma J P., Robust adaptive attitude tracking control of spacecraft with constrained inputs, Control and Decision, 36, 9, pp. 2297-2304, (2021)
[3] Astolfi A, Ortega R., Immersion and invariance: A new tool for stabilization and adaptive control of nonlinear systems, IEEE Transactions on Automatic Control, 48, 4, pp. 590-606, (2003)
[4] Liu X B, Ortega R, Su H Y, Et al., Immersion and invariance adaptive control of nonlinearly parameterized nonlinear systems, IEEE Transactions on Automatic Control, 55, 9, pp. 2209-2214, (2010)
[5] Lou Z E, Zhao J., Immersion and invariance stabilization of switched nonlinear systems under arbitrary switchings, The 35th Chinese Control Conference, pp. 1617-1620, (2016)
[6] Yang Y, Song S., Distributed consensus tracking control of a second-order nonlinear multiagent system via immersion and invariance method, IEEE Systems Journal, 14, 17, pp. 2573-2581, (2020)
[7] Zhao B, Xian B, Zhang Y, Et al., Nonlinear robust adaptive tracking control of a quadrotor UAV via immersion and invariance methodology, IEEE Transactions on Industrial Electronics, 62, 5, pp. 2891-2902, (2015)
[8] Bai Y, Wang Y J, Svinin M, Et al., Function approximation technique based immersion and invariance control for unknown nonlinear systems, IEEE Control Systems Letters, 4, 4, pp. 934-939, (2020)
[9] Han C, Liu Z, Yi J Q., Immersion and invariance adaptive control with σ-modification for uncertain nonlinear systems, Journal of the Franklin Institute, 355, 5, pp. 2091-2111, (2018)
[10] Seo D, Akella M R., Non-certainty equivalent adaptive control for robot manipulator systems, Systems & Control Letters, 58, 4, pp. 304-308, (2009)

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