Adaptive Controller Design for Teleoperation System with Actuator Saturation

The output-feedback based controller design problem is investigated for the networked teleoperation system in this chapter. A new control scheme is proposed to guarantee the global asymptotic stability of the bilateral teleoperation system with time-varying delays and bounded inputs. Firstly, a new fast terminal sliding mode velocity observer is proposed to estimate the unknown velocity signals for the teleoperation system. Then, by considering the unknown gravity term, an adaptive SP+Sd-type (saturated proportion plus saturated damping) controller is designed based on the estimated velocity. In the new controllers, the specific sigmoidal function is not used, and any one on a set of saturation functions can be applied. Furthermore, by choosing Lyapunov-Krasovskii functional, we show that the master-slave teleoperation system is stable under specific linear matrix inequality (LMI) conditions. With the given controller design parameters and the upper bound of the input, the allowable maximal transmission delay can be computed by using the proposed stability criteria. Finally, both simulation and experiment are performed to show the effectiveness of the proposed methods.

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