Observer-based multivariable fixed-time formation control of mobile robots 被引量：1

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摘要 This paper proposes a multivariable fixed-time leaderfollower formation control method for a group of nonholonomic mobile robots, which has the ability to estimate multiple uncertainties. Firstly, based on the state space model of the leader-follower formation, a multivariable fixed-time formation kinematics controller is designed. Secondly, to overcome uncertainties existing in the nonholonomic mobile robot system, such as load change,friction, external disturbance, a multivariable fixed-time torque controller based on the fixed-time disturbance observer at the dynamic level is designed. The designed torque controller is cascaded with the formation controller and finally realizes accurate estimation of the uncertain part of the system, the follower tracking of reference velocity and the desired formation of the leader and the follower in a fixed-time. The fixed-time upper bound is completely determined by the controller parameters, which is independent of the initial state of the system. The multivariable fixed-time control theory and the Lyapunov method are adopted to ensure the system stability.Finally, the effectiveness of the proposed algorithm is verified by the experimental simulation.

作者 LI Yandong ZHU Ling and GUO Yuan

机构地区 College of Computer and Control Engineering School of Mechanical and Electronic Engineering

出处《Journal of Systems Engineering and Electronics》 SCIE EI CSCD 2020年第2期403-414,共12页 系统工程与电子技术（英文版）

基金 supported by the National Natural Science Foundation of China(61872204) the Natural Science Foundation of Heilongjiang Province of China(F2015025)。

关键词 MULTIVARIABLE fixed-time CONTROL formation CONTROL uncertainty fixed time OBSERVER NONHOLONOMIC mobile robot

分类号 TP242 [自动化与计算机技术—检测技术与自动化装置]

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参考文献1

1朱玲,李艳东,孙明,王宗义.移动机器人编队的神经网络滑模控制[J].电机与控制学报,2014,18(3):113-118. 被引量：15

二级参考文献16

1贾秋玲,闫建国,王新民.基于势函数的多机器人系统的编队控制[J].机器人,2006,28(2):111-114. 被引量：13
2俞辉,王永骥,徐建省.非完整移动机器人编队的滑模控制[J].机器人,2006,28(4):428-432. 被引量：7
3BALCH T, ARKIN R C. Behavior-based formation control for multi-robot teams[ J]. IEEE Transactions on Robotics and Auto- mation, 1998, 14(6) : 926 -939.
4LEWIS M A, TAN K H. High precision formation control of mo- bile robots using virtual structures [ J ]. Autonomous Robots, 1997, 4(4) : 387 -403.
5THIJS H A, NATHAN V D W, NIJMEIJER H. Formation control of unicycle mobile robots : a virtual structure approach [ C ]//Joint 48th IEEE Conference on Decision and control and 28th Chinese Control Conterence, December 16- 18, 2009, Shanghai, China. 2009 : 8328 - 8333.
6DESAI J P, OSTROWSKI J P, KUMAR V. Modeling and control of formations of nonholonomic mobile robots [ J ]. IEEE Transac- tions on Robotics and Automation, 2001, 17 (6) :905 - 908.
7TANNER H G, PAPPAS G J, KUMAR V. Leader-to-formationstability [ J]. IEEE Transactions on Robotics and Automation 2004, 20(3) :443 -455.
8DIERKS T, JAGANNATHAN S. Control of nonholonomic mobile robot formations : backstepping kinematics into dynamics [ C ]// 16th IEEE International Conference on Control Applications Part of IEEE Multi-conference on Systems and Control, October 1 - 3, 2007, Singapore. 2007:94 - 99.
9DONG W J, FARRELL Jay A. Decentralized cooperative control of multiple nonholonomic dynamic systems with uncertainty [ J ]. Automatica, 2009,45 ( 3 ) : 706 - 710.
10DAS A, FIERRO R, KUMAR V, et al. A vision-based forma- tion control framework [ J 1. IEEE Transactions on Robotics and Automation, 2002, 18 (5) : 813 - 825.