Integrated adaptive robust control for multilateral teleoperation systems under arbitrary time delays

• Published in: International journal of robust and nonlinear control Vol. 26; no. 12; pp. 2708 - 2728
• Main Authors: Chen, Zheng, Pan, Ya-Jun, Gu, Jason
• Format: Journal Article
• Language: English
• Published: Bognor Regis Blackwell Publishing Ltd 01.08.2016; Wiley Subscription Services, Inc
• Subjects: Control systems; Force distribution; Manipulators; Mathematical models; Multilateral; multilateral teleoperation; nonlinear adaptive robust control; Nonlinearity; Robot arms; robotics; Synchronism; time delay; uncertain systems
• ISSN: 1049-8923; 1099-1239
• DOI: 10.1002/rnc.3472

Summary With the increasing industrial requirements such as bigger size object, stable operation, and complex task, multilateral teleoperation systems extended from traditional bilateral teleoperation are widely developed. In this paper, the integrated control design is developed for multilateral teleoperation systems, where n master manipulators are operated by human to remotely control n slave manipulators cooperatively handling a target object. For the first time, the control objectives of multilateral teleoperation including stability, synchronization, transparency, and internal force distribution are clarified systematically. A novel communication architecture is proposed to cope with communication delays, where the estimated environmental parameters are transmitted from the slave side to the master, to replace the traditional environmental force measurement in the communication channel. A kind of nonlinear adaptive robust control technique is used to deal with nonlinearities, unknown parameters, and modeling uncertainties existing in the master, slave, and environmental dynamics, so that the excellent tracking performance is achieved in both master and slave sides. The coordinated motion/force control is designed in the slave side by the optimal internal force distribution among n slave manipulators, and the impedance control is designed in the master side to realize the target transparency behavior. In summary, the proposed control algorithm can achieve the guaranteed robust stability, the excellent synchronization and transparency performance, and the optimal internal force distribution simultaneously for multilateral teleoperation systems under arbitrary time delays and various modeling uncertainties. The simulation is carried out on a 2‐master/2‐slave teleoperation system, and the results show the effectiveness of the proposed control design. Copyright © 2015 John Wiley & Sons, Ltd.