Data-driven model-free predictive control for microstage with coupling and hysteresis nonlinearities

IF 2.7 4区计算机科学 Q2 AUTOMATION & CONTROL SYSTEMS Asian Journal of Control Pub Date : 2024-04-14 DOI:10.1002/asjc.3386

Shiqi Lin, Xuesong Chen

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Abstract

The precision motion control problem is investigated in this paper for microstages with cross-axial coupling and hysteresis. Cross-axis coupling generally results in stress-stiffening effects, thereby causing time-varying dynamics in the microstages. Additionally, when a microstage is driven by piezoelectric actuators (PEAs), the hysteresis effect of the actuator itself must also be considered. Modeling the microstages becomes complicated when both nonlinear characteristics, coupling and hysteresis, coexist. To address this challenge without the need for modeling, a novel data-driven model-free predictive control scheme called first-order tensor-vector product polynomial approximation based model-free predictive control (TPPA $_{1}$ -MFPC is proposed. TPPA $_{1}$ -MFPC solely relies on the sampling input/output (I/O) data of the systems. The main concept behind TPPA $_{1}$ -MFPC is to derive a linear approximation model using the I/O data collected during operation. This linear approximation model then serves as a nominal model in a predictive controller, enabling the control of the microstages. Finally, the effectiveness of the proposed TPPA $_{1}$ -MFPC scheme and the performance improvement over existing model-free schemes, for example, proportion integration differentiation control (PID), model-free adaptive control (MFAC), model-free adaptive predictive control (MFAPC), data-dependent LMI (DDLMI), and data-enabled predictive control (DeePC) are demonstrated in the simulation examples with a 2-degree of freedom (DOF) multileaf spring-based microstage driven by PEA.

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针对具有耦合和滞后非线性的微舞台的数据驱动型无模型预测控制

摘要本文研究了具有交叉轴耦合和滞后现象的微动平台的精密运动控制问题。交叉轴耦合通常会产生应力刚化效应，从而导致微动平台产生时变动态。此外，当微型平台由压电致动器（PEA）驱动时，还必须考虑致动器本身的滞后效应。当耦合和滞后这两种非线性特性同时存在时，微舞台的建模就会变得复杂。为了在不需要建模的情况下应对这一挑战，我们提出了一种新颖的数据驱动型无模型预测控制方案，即基于一阶张量矢量乘多项式近似的无模型预测控制（TPPA -MFPC）。TPPA -MFPC完全依赖于对系统输入/输出（I/O）数据的采样。TPPA -MFPC 背后的主要概念是利用运行期间收集的 I/O 数据推导出一个线性近似模型。然后，该线性近似模型将作为预测控制器的标称模型，实现对微型阶段的控制。最后，通过一个由 PEA 驱动的 2 自由度 (DOF) 多叶弹簧式微舞台的仿真实例，证明了所提出的 TPPA -MFPC 方案的有效性，以及与现有无模型方案（例如比例积分微分控制 (PID)、无模型自适应控制 (MFAC)、无模型自适应预测控制 (MFAPC)、数据相关 LMI (DDLMI) 和数据支持预测控制 (DeePC) 相比的性能改进。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Asian Journal of Control 工程技术-自动化与控制系统

CiteScore

4.80

自引率

25.00%

发文量

253

审稿时长

7.2 months

期刊介绍： The Asian Journal of Control, an Asian Control Association (ACA) and Chinese Automatic Control Society (CACS) affiliated journal, is the first international journal originating from the Asia Pacific region. The Asian Journal of Control publishes papers on original theoretical and practical research and developments in the areas of control, involving all facets of control theory and its application. Published six times a year, the Journal aims to be a key platform for control communities throughout the world. The Journal provides a forum where control researchers and practitioners can exchange knowledge and experiences on the latest advances in the control areas, and plays an educational role for students and experienced researchers in other disciplines interested in this continually growing field. The scope of the journal is extensive. Topics include: The theory and design of control systems and components, encompassing: Robust and distributed control using geometric, optimal, stochastic and nonlinear methods Game theory and state estimation Adaptive control, including neural networks, learning, parameter estimation and system fault detection Artificial intelligence, fuzzy and expert systems Hierarchical and man-machine systems All parts of systems engineering which consider the reliability of components and systems Emerging application areas, such as: Robotics Mechatronics Computers for computer-aided design, manufacturing, and control of various industrial processes Space vehicles and aircraft, ships, and traffic Biomedical systems National economies Power systems Agriculture Natural resources.

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