A Tactile Lightweight Exoskeleton for Teleoperation: Design and Control Performance

In this work, an upgraded exoskeleton design is presented with enhanced trajectory tracking and mechanical transparency. Compared to the first version, the design features a 3-DoF actuated shoulder joint and a mechanism to regulate the pretension of Bowden cables. Force/torque sensors are installed to directly measure the interaction forces between the human arm and the exoskeleton at the connecting points. Three control strategies were evaluated to follow a desired trajectory; A PD controller, a PD controller with friction observer, and an adaptive controller based on Radial Basis Function (RBF). These strategies also form the basis for an admittance control, aimed at improving the exoskeleton’s mechanical transparency during interaction with the human arm. Simulations and experimental results demonstrate that the PD control, supported by friction estimation via a momentum observer, achieves superior tracking performance. Moreover, the system’s mechanical transparency is enhanced using the admittance RBF-based controller, showing marginally superior results.