Neural Network-Based Control of Networked Trilateral Teleoperation With Geometrically Unknown Constraints

Most studies on bilateral teleoperation assume known system kinematics and only consider dynamical uncertainties. However, many practical applications involve tasks with both kinematics and dynamics uncertainties. In this paper, trilateral teleoperation systems with dual-master-single-slave framewor...

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Veröffentlicht in:	IEEE transactions on cybernetics 2016-05, Vol.46 (5), p.1051-1064
Hauptverfasser:	Li, Zhijun, Xia, Yuanqing, Wang, Dehong, Zhai, Di-Hua, Su, Chun-Yi, Zhao, Xingang
Format:	Artikel
Sprache:	eng
Schlagworte:	Computer simulation Control systems Delay Delays Dynamical systems Dynamics Force Hybrid force-motion control kinematic uncertainty Kinematics networked trilateral teleoperation Neural networks Robot kinematics Uncertainty
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creator	Li, Zhijun Xia, Yuanqing Wang, Dehong Zhai, Di-Hua Su, Chun-Yi Zhao, Xingang
description	Most studies on bilateral teleoperation assume known system kinematics and only consider dynamical uncertainties. However, many practical applications involve tasks with both kinematics and dynamics uncertainties. In this paper, trilateral teleoperation systems with dual-master-single-slave framework are investigated, where a single robotic manipulator constrained by an unknown geometrical environment is controlled by dual masters. The network delay in the teleoperation system is modeled as Markov chain-based stochastic delay, then asymmetric stochastic time-varying delays, kinematics and dynamics uncertainties are all considered in the force-motion control design. First, a unified dynamical model is introduced by incorporating unknown environmental constraints. Then, by exact identification of constraint Jacobian matrix, adaptive neural network approximation method is employed, and the motion/force synchronization with time delays are achieved without persistency of excitation condition. The neural networks and parameter adaptive mechanism are combined to deal with the system uncertainties and unknown kinematics. It is shown that the system is stable with the strict linear matrix inequality-based controllers. Finally, the extensive simulation experiment studies are provided to demonstrate the performance of the proposed approach.
doi_str_mv	10.1109/TCYB.2015.2422785
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However, many practical applications involve tasks with both kinematics and dynamics uncertainties. In this paper, trilateral teleoperation systems with dual-master-single-slave framework are investigated, where a single robotic manipulator constrained by an unknown geometrical environment is controlled by dual masters. The network delay in the teleoperation system is modeled as Markov chain-based stochastic delay, then asymmetric stochastic time-varying delays, kinematics and dynamics uncertainties are all considered in the force-motion control design. First, a unified dynamical model is introduced by incorporating unknown environmental constraints. Then, by exact identification of constraint Jacobian matrix, adaptive neural network approximation method is employed, and the motion/force synchronization with time delays are achieved without persistency of excitation condition. The neural networks and parameter adaptive mechanism are combined to deal with the system uncertainties and unknown kinematics. It is shown that the system is stable with the strict linear matrix inequality-based controllers. 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subjects	Computer simulation Control systems Delay Delays Dynamical systems Dynamics Force Hybrid force-motion control kinematic uncertainty Kinematics networked trilateral teleoperation Neural networks Robot kinematics Uncertainty
title	Neural Network-Based Control of Networked Trilateral Teleoperation With Geometrically Unknown Constraints
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