轮式移动机器人轨迹跟踪控制研究

计算机工程与科学 ›› 2022, Vol. 44 ›› Issue (10): 1804-1811.

轮式移动机器人轨迹跟踪控制研究

张小俊,刘昊学

(河北工业大学机械工程学院，天津 300401)

收稿日期:2021-06-01 修回日期:2021-07-05 接受日期:2022-10-25 出版日期:2022-10-25 发布日期:2022-10-28
基金资助:
国家重点研发计划(2018YFB1309401)

Research on trajectory tracking control of wheeled mobile robot

ZHANG Xiao-jun,LIU Hao-xue

(School of Mechanical Engineering，Hebei University of Technology,Tianjin 300401,China)

Received:2021-06-01 Revised:2021-07-05 Accepted:2022-10-25 Online:2022-10-25 Published:2022-10-28

摘要/Abstract

摘要： 针对轮式移动机器人参数摄动和内外部扰动等问题，提出一种新型的基于自适应扩张状态观测器的滑模控制算法。采用自适应虚拟速度控制器估计系统未知参数，滑模控制器抑制参数摄动和内外部扰动，非线性扩张状态观测器观测系统扰动并减小控制输入的抖振，实现了轨迹跟踪误差的快速收敛。利用Lyapunov稳定性理论证明了控制算法的稳定收敛性。将所提算法与传统自适应反演滑模算法进行对比，对比结果表明了所提算法的有效性和鲁棒性。

关键词: 轮式移动机器人, 轨迹跟踪控制, 扩张状态观测器, 滑模控制器, 自适应虚拟速度控制器

Abstract: Aiming at the problems of parameter perturbation and internal and external disturbances of wheeled mobile robots, a novel sliding mode control algorithm based on adaptive extended state observer is proposed. An adaptive virtual velocity controller is used to estimate unknown parameters of the system, a sliding mode controller is used to suppress parameter perturbations and internal and external disturbances, and a nonlinear extended state observer is used to observe system perturbations and reduce the chattering of the control inputs, so the trajectory tracking error is rapidly converging. Lyapunov theory is adopted to prove the stable convergence of the control system. The proposed algorithm is compared with the traditional adaptive inversion sliding mode algorithm, and the results show the effectiveness and robustness of the proposed control strategy.

Key words: wheeled mobile robot, trajectory tracking control, extended state observer, sliding mode controller, adaptive virtual speed controller

张小俊, 刘昊学. 轮式移动机器人轨迹跟踪控制研究[J]. 计算机工程与科学, 2022, 44(10): 1804-1811.

ZHANG Xiao-jun, LIU Hao-xue. Research on trajectory tracking control of wheeled mobile robot[J]. Computer Engineering & Science, 2022, 44(10): 1804-1811.

参考文献［20］

［1］	Liang P,Gao X,Zhang Q,et al.Design and stability analysis of a wall-climbing robot using propulsive force of propeller［J］.Symmetry,2021,13(1):37-40.
［2］	Tu C L, Jin S S,Zheng K,et al.Support and positioning mechanism of a detection robot inside a spherical tank［J］.Chinese Journal of Mechanical Engineering,2021,34(1):1-10.
［3］	Wang Yang,Zhang Xiao-jun,Zhang Ming-lu,et al.Design and analysis of split-flexible wall-climbing robot with adaptive variable curvature facade［J］.Journal of Mechanical Engineering,2021,57(3):49-58.(in Chinese)
［4］	Li B,Ushiroda K,Yang L,et al.Wall-climbing robot for non-destructive evaluation using impact-echo and metric learning SVM［J］.International Journal of Intelligent Robotics and Applications,2017,1(3):255-270.
［5］	Gu Wan-li,Hu Yun-feng,Gong Xun,et al.Trajectory tracking control of mobile robot considering parameter uncertainty［J］.Control and Decision,2019,34(1):81-88.(in Chinese)
［6］	Bao Xue, Wang Da-zhi,Hu Ming.Backstepping sliding mode control design for spinning ammunition based on adaptive fuzzy method［J］.Chinese Journal of Scientific Instrument,2016,37(6):1333-1339.(in Chinese)
［7］	Xin L,Li P L,Yang L,et al.Back-stepping fuzzy adaptive sliding mode trajectory tracking control for wall-climbing robot［J］.Journal of Computers,2019,14(12):662-679.
［8］	Koubaa Y,Boukattaya M,Damak T.Adaptive sliding mode control for trajectory tracking of nonholonomic mobile robot with uncertain kinematics and dynamics［J］.Applied Artificial Intelligence,2018,32(9-10):924-938.
［9］	Zhang Cheng-ju,Wang Cong,Cao Wei,et al.Adaptive neural network trajectory tracking control for underactuated unmanned surface vehicle［J］.Journal of Harbin Institute of Technology,2020,52(12):1-7.(in Chinese)
［10］	Cui M,Huang R,Liu H,et al.Adaptive tracking control of wheeled mobile robots with unknown longitudinal and late- ral slipping parameters［J］.Nonlinear Dynamics,2014,78(3):1811-1826.
［11］	Chen M. Disturbance attenuation tracking control for wheeled mobile robots with skidding and slipping［J］.IEEE Transactions on Industrial Electronics,2016,64(4):3359-3368.
［12］	Li L,Wang T,Xia Y,et al.Trajectory tracking control for wheeled mobile robots based on nonlinear disturbance observer with extended Kalman filter［J］.Journal of the Franklin Institute,2020,357(13):8491-8507.
［13］	Dian S, Fang H,Zhao T,et al.Modeling and trajectory tracking control for magnetic wheeled mobile robots based on improved dual-heuristic dynamic programming［J］.IEEE Transactions on Industrial Informatics,2020,17(2):1470-1482.
［14］	Kang H S,Kim Y T,Hyun C H,et al.Generalized extended state observer approach to robust tracking control for wheeled mobile robot with skidding and slipping［J］.International Journal of Advanced Robotic Systems,2013,10(3):155-162.
［15］	Alipour K,Robat A B,Tarvirdizadeh B.Dynamics modeling and sliding mode control of tractor-trailer wheeled mobile robots subject to wheels slip［J］.Mechanism and Machine Theory,2019,138(3):16-37.
［16］	Sen P T H,Minh N Q,Minh P X.A new tracking control algorithm for a wheeled mobile robot based on backstepping and hierarchical sliding mode techniques［C］∥Proc of the 1st International Symposium on Instrumentation,Control,Artificial Intelligence,and Robotics,2019: 25-28.
［17］	Asif M,Khan M J,Cai N.Adaptive sliding mode dynamic controller with integrator in the loop for nonholonomic wheeled mobile robot trajectory tracking［J］.International Journal of Control,2014,87(5):964-975.
［18］	Chen H,Yan D,Chen H,et al.A sliding-mode-like design for model-free tracking of nonholonomic mobile robots［C］∥Proc of the 14th International Workshop on Variable Structure Systems,2016: 43-46.
［19］	Dian S, Fang H,Zhao T,et al.Modeling and trajectory tracking control for magnetic wheeled mobile robots based on improved dual-heuristic dynamic programming［J］.IEEE Transactions on Industrial Informatics,2020,17(2):1470-1482.
［20］	Zhang Sen,Zhang Yuan-heng,Pu Jie-xin,et al.Adaptive inversion sliding mode control of wheeled mobile welding robot［J］.Fire Control & Command Control,2018,43(7):65-70.(in Chinese)
	附中文参考文献：
［3］	王洋,张小俊,张明路,等.可自适应变曲率立面的分体柔性爬壁机器人设计与分析［J］.机械工程学报,2021,57(3):49-58.
［5］	顾万里,胡云峰,宫洵,等.考虑参数不确定性的移动机器人轨迹跟踪控制［J］.控制与决策,2019,34(1):81-88.
［6］	鲍雪,王大志,胡明.基于自适应模糊的旋转弹反演滑模控制律设计［J］.仪器仪表学报,2016,37(6):1333-1339.
［9］	张成举,王聪,曹伟,等.欠驱动USV神经网络自适应轨迹跟踪控制［J］.哈尔滨工业大学学报,2020,52(12):1-7.
［20］	张森,张元亨,普杰信,等.轮式移动焊接机器人自适应反演滑模控制［J］.火力与指挥控制,2018,43(7): 65-70.