基于扩张状态观测器的快速步进/凝视成像机构控制

黄浦; 杨秀丽; 修吉宏; 李军; 李友一; 许永森

doi:doi:10.3788/ope.20182608.2084

光学精密工程, 2018, 26 (8): 2084, 网络出版: 2018-10-02

基于扩张状态观测器的快速步进/凝视成像机构控制

Extended state observer based control of fast step/stare imaging mechanisms

论文大纲

黄浦 ¹杨秀丽 ²修吉宏 ¹李军 ¹李友一 ¹许永森 ¹

作者单位

¹ 中国科学院长春光学精密机械与物理研究所中国科学院航空光学成像与测量重点实验室, 吉林长春 130033

² 空军航空大学, 吉林长春 130022

摘要

提出一种基于扩张状态观测器并引入加速度补偿策略的控制器设计方案, 以实现快速步进/凝视成像机构对控制性能的高要求。首先, 阐述了扩张状态观测器理论, 对其特性进行了详细分析, 并设计了以成像机构为被控对象的三阶线性扩张状态观测器。通过将观测器置于速度内环反馈通道, 设计了基于扩张状态观测器的位置和速度双回路控制器。在此基础上, 利用观测器输出的加速度估计值, 提出加速度补偿策略, 并设计了补偿环节。实验结果表明, 与无加速度补偿环节相比, 引入加速度补偿后, 成像机构每次步进调节时间由76 ms减小到33 ms, 凝视期间的角位置精度由约0.07°减小到0.01°以内, 速度波动减小约2～3倍, 成像机构的控制性能明显改善。控制器设计简单, 需整定参数少, 对于提高同类控制系统性能具有较高的实用价值。

Abstract

An extended state observer (ESO) based controller with acceleration compensation strategy was proposed to satisfy the high requirements for control performance of fast step/stare imaging mechanisms. First, the theory of ESO was described and its characteristics were expatiated. Then, the third-order linear extended state observer (LESO) was designed with an imaging mechanism as the controlled object. By placing the observer in the feedback channel of the speed loop, a double loop controller of position and speed based on an ESO was designed. On this basis, an acceleration compensation strategy was proposed, and the compensating link was described using the estimated acceleration output by the observer. The experiment results showed that the settling time of the imaging mechanism was reduced at every step from 76 ms to 33 ms and the accuracy of the angular position during the period of stare decreased approximately 0.07°to 0.01°. In addition, the speed fluctuation was reduced by approximately two to three times compared with that without acceleration compensation. The control performance of the mechanism was significantly improved to meet high-performance requirements. The design process of the controller was simple and the adjusted parameters were less than that of traditional designs, which is of high practical value in terms of improving the performance of similar control systems.

参考文献

[1] 高志强．控制工程的抗扰范式［C］．第二十九届中国控制会议论文集, 北京: 2010: 6071-6076．

GAO ZH Q．On Disturbance Rejection Paradigm in Control Engineering［C］．Proceedings of the 29th Chinese Control Conference, Beijing, China, 2010: 6071-6076．(in Chinese)

[2] 黄浦, 修吉宏, 李军, 等．航空相机镜筒位置控制的扰动估计与补偿［J］．光学精密工程, 2012, 20(4): 803-810．

HUANG P, XIU J H, LI J, et al.． Disturbance estimation and compensation of position control of lensbarrels in aerial cameras［J］．Opt．Precision Eng．, 2012, 20(4): 803-810． (in Chinese)

[3] 韩京清．从PID技术到“自抗扰控制”技术［J］．控制工程, 2002, 9(3): 13-18．

HAN J Q． From PID Technique to Active Disturbance Rejection Control Technique ［J］．CONTROL Engineering of China, 2002, 9(3): 13-18． (in Chinese)

[4] 崔宁, 陈兴林, 曹开锐, 等．空间光通信精跟踪系统的模糊自抗扰控制［J］．光学精密工程, 2015, 23(5): 1394-1400．

CUI N, CHEN X L, CAO K R, et al.．Fuzzy active disturbance rejection control of fine tracking system for free space optical communication［J］．Opt．Precision Eng．, 2015, 23(5): 1394-1400． (in Chinese)

[5] 彭树萍, 李博, 姜润强, 等．光电跟踪系统的双模控制［J］．光学精密工程, 2016, 24(2): 335-342．

PENG SH P, LI B, JIANG R Q, et al.．Dual mode control for electro-optical tracking systems［J］．Opt．Precision Eng., 2016, 24(2): 335-342． (in Chinese)

[6] 周旺平, 刘文, 刘伟．斜轴式天文望远镜机架的驱动控制［J］．光学精密工程, 2015, 23(6): 1664-1672．

ZHOU W P, LIU W, LIU W．Driving control for mounting rack of slant axis astronomical telescopes［J］．Opt．Precision Eng．, 2015, 23(6): 1664-1672． (in Chinese)

[7] YOO D, YAU S S T, GAO Z． Optimal fast tracking observer bandwidth of the linear extended state observer［J］．International Journal of Control, 2007, 80(1): 102-111．

[8] XIA Y Q,ZHU ZH,FU M Y, et al．Attitude Tracking of Rigid Spacecraft With Bounded Disturbances ［J］．IEEE Transactions on Industral Electronics, 2011, 58(2): 647-659．

[9] JOHN VINCENT, DAN MORRIS, NATHAN USHER, et al.． On Active Disturbance Rejection Based Control Design for Superconducting RF Cavities ［J］．Nuclear Instruments and Methods in Physics Research A, 2011, 643(1): 11-16．

[10] 韩京清．自抗扰控制技术—估计补偿不确定因素的控制技术［M］．北京: 国防工业出版社, 2008．

HAN J Q．Active Disturbance Rejection Control Technique-the technique for estimating and compensating the uncertainties ［M］．Beijing: National Defense Industry Press, 2008．(in Chinese)

[11] SANJAY E． Talole, Jayawant P． Kolhe, Srivijay B． Phadke． Extended-State-Observer-Based Control of Flexible-Joint System With Experimental Validation ［J］．IEEE Transactions on Industrial Electronics, 2010, 57(4): 1411-1419．

[12] GAO ZH Q.Scaling and Bandwidth-Parameterization Based Controller Tuning［C］．Proceedings of American Control Conference, 2003, 4989-4996．

[13] TIAN G,GAO ZH Q．Benchmark Tests of Active Disturbance Rejection Control on an Industrial Motion Control Platform［C］．Proceedings of the 2009 American Control Conference, 2009: 5552-5557．

[14] DONG L L, Prasanth Kandula, GAO ZH Q,et al.．On a robust control system design for an electric power assist steering system ［C］．Proceedings of the 2010 American Control Conference, 2010: 5356-5361．

[15] DONG L L,ZHENG Q,GAO ZH Q．On Control System Design for Convertional Mode of Operation of Vibrational gyroscopes ［J］．IEEE SENSORS JOURNAL, 2008, 8(11): 1871-1878．

[16] GEORGE ELLIS．Control System Design Guide(Fourth Edition) ［M］．ELSEVIER, 2012．

[17] LI SH H,LIU ZH G．Adaptive Speed Control for Permanent-Magnet Synchronous Motor System With Variations of Load Inertia ［J］．IEEE Transactions on Industral Electronics, 2009, 56(8): 3050-3059．

[18] 王建立．光电经纬仪电视跟踪、捕获快速运动目标计数的研究［D］．北京: 中国科学院研究生院, 2002．

WANG J L． Study on TV tracking system of O-E theodolite to track and acquire fast moving targets ［D］．Beijing: Graduate University of Chinese Academy of Sciences , 2002． (in Chinese)

黄浦, 杨秀丽, 修吉宏, 李军, 李友一, 许永森. 基于扩张状态观测器的快速步进/凝视成像机构控制[J]. 光学精密工程, 2018, 26(8): 2084. HUANG Pu, YANG Xiu-li, XIU Ji-hong, LI Jun, LI You-yi, XU Yong-sen. Extended state observer based control of fast step/stare imaging mechanisms[J]. Optics and Precision Engineering, 2018, 26(8): 2084.

基于扩张状态观测器的快速步进/凝视成像机构控制

关于本站 Cookie 的使用提示

全站搜索

基于扩张状态观测器的快速步进/凝视成像机构控制

相关论文

相关资讯

关于本站 Cookie 的使用提示

全站搜索