An Improved Wave-Variable Based Four-Channel Control Design in Bilateral Teleoperation System for Time-Delay Compensation

Good transparency performance (including position tracking and force feedback) is a significant issue for teleoperation control design. The four-channel control approach, which is based on the impedance matching between the master and slave, is an effective method to achieve the perfect transparency performance of teleoperation system. However, the obvious drawback of this design is that the time delay existing in the communication channel is neglected and thus the stability of this design under time delay cannot be guaranteed. Some passivity based control approaches such as wave-variable are developed to handle the stability problem of teleoperation system under time delay, and have been tried to add into four-channel control design. Though the stability under time delay is achieved for this kind of design, the transparency performance may largely decrease since the traditional wave-variable may essentially suffer some performance limitations (e.g., wave reflection). Thus, simultaneously realizing the stability and good transparency performance for four channel teleoperation system is still a challenging issue. In this paper, an improved wave-variable based four-channel control design is developed for bilateral teleoperation system to guarantee stability and further improve transparency performance. Under four channel control architecture, the passivity based time-delay compensator by the modified wave transform and the local force feedback are provided to compensate the distortion by reducing wave reflection and further enhance the stability and transparency of teleoperation system. The experiment is carried out, and the results show the great improvement of the proposed method to achieve the good transparency performance compared to the previous four-channel control designs.