引用本文:俞经睿,朱毅成,冉晨阳,苏剑波.基于自抗扰控制的机器人定位策略[J].控制理论与应用,2023,40(4):772~779.[点击复制]
YU Jing-rui,ZHU Yi-chen,RAN Chen-yang,SU Jian-bo.Robot localization based on active disturbance rejection controller[J].Control Theory and Technology,2023,40(4):772~779.[点击复制]
基于自抗扰控制的机器人定位策略
Robot localization based on active disturbance rejection controller
摘要点击 1529  全文点击 425  投稿时间:2021-11-10  修订日期:2022-05-11
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DOI编号  10.7641/CTA.2022.11091
  2023,40(4):772-779
中文关键词  定位  抗干扰  机器人
英文关键词  localization  disturbance rejection  robot
基金项目  国家自然科学基金项目(61533012, 91748120, 52041502)
作者单位E-mail
俞经睿 上海交通大学 yujingrui@sjtu.edu.cn 
朱毅成 上海交通大学 zhu-yicheng@sjtu.edu.cn 
冉晨阳 上海交通大学 rancheny@sjtu.edu.cn 
苏剑波* 上海交通大学 jbsu@sjtu.edu.cn 
中文摘要
      机器人定位即需根据传感器测量对自身位置进行估计. 由于机器人系统模型的复杂非线性, 工况环境中的不确定干扰, 定位结果不可避免地会受到系统内外扰动的影响. 现有的定位算法往往仅能依赖模型或传感配置以及算法自身的鲁棒性被动抗扰, 这使得定位系统的抗扰能力有限、应用场景受限. 本文基于自抗扰控制思想提出一种 能够主动补偿系统内外扰动的机器人定位策略. 该策略将系统中所有能够影响最终定位结果的不确定因素统一视为总扰动, 并设计扩张状态观测器实现对总扰动的观测, 在此基础上构建控制器补偿总扰动影响, 以使定位结果更加准确. 与传统的定位抗扰策略相比, 本文所提出的抗扰定位策略并不依赖于模型或特定的传感配置, 能够处理任意有界的扰动类型, 理论上能够成为定位抗干扰的终极解决路径. 最后, 基于李雅普诺夫理论证明了系统的稳定性. 仿真和实车实验验证了本文提出的基于自抗扰控制的机器人定位策略能够有效地观测系统总扰动, 并补偿扰动影响, 提高定位结果的准确度.
英文摘要
      Robot localization refers to the estimation of its own position based on sensor measurements. Due to the complexity of nonlinear robot systems and the disturbances in the working environment, the localization results are inevitably affected by the internal and external disturbances. Existing localization algorithms adopt a passive disturbance-rejection strategy, relying on the robustness of the algorithm itself to cope with uncertainty, and often depend on models or specific sensing configurations, which leads to limited disturbance-rejection capability and restricted application scenarios. In this paper, we propose a novel robot localization framework that can actively cope with both internal and external uncertainties of the systems. All uncertainties that affect the localization results are uniformly considered as a total disturbance. The extended state observer is designed to estimate the total disturbance, and the controller is applied to compensate the total disturbance and to improve the accuracy of localization. Compared with the traditional localization frameworks, the proposed approach is independent of specific system configurations, and can also handle arbitrary bounded disturbances, resulting in more universal, robust and effective disturbance-rejection localization strategies. Finally, the stability of the system is proved based on the Lyapunov theory. The results of simulations and a real platform-based experiment verify the effectiveness and satisfactory performance of the proposed localization framework.