Disturbance rejection via iterative learning control with a disturbance observer for active magnetic bearing systems

被引：0

作者：

Ze-zhi Tang

Yuan-jin Yu

Zhen-hong Li

Zheng-tao Ding

机构：

[1] University of Manchester,School of Electrical and Electronic Engineering

[2] James Lighthill Building,Sino

来源：

Frontiers of Information Technology & Electronic Engineering | 2019年 / 20卷

关键词：

Active magnetic bearings (AMBs); Iterative learning control (ILC); Disturbance observer; TP27; TH133;

D O I：

暂无

中图分类号：

学科分类号：

摘要：

Although standard iterative learning control (ILC) approaches can achieve perfect tracking for active magnetic bearing (AMB) systems under external disturbances, the disturbances are required to be iteration-invariant. In contrast to existing approaches, we address the tracking control problem of AMB systems under iteration-variant disturbances that are in different channels from the control inputs. A disturbance observer based ILC scheme is proposed that consists of a universal extended state observer (ESO) and a classical ILC law. Using only output feedback, the proposed control approach estimates and attenuates the disturbances in every iteration. The convergence of the closed-loop system is guaranteed by analyzing the contraction behavior of the tracking error. Simulation and comparison studies demonstrate the superior tracking performance of the proposed control approach.

引用

页码：131 / 140

页数：9

共 60 条

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