
arXiv: 2208.05065
AbstractThis article proposes a novel fixed‐time integral sliding mode controller for admittance control to enhance physical human‐robot collaboration. The proposed method combines the benefits of compliance to external forces of admittance control and high robustness to uncertainties of integral sliding mode control (ISMC), such that the system can collaborate with a human partner in an uncertain environment effectively. First, a fixed‐time sliding surface is applied in the ISMC to make the tracking error of the system converge within a fixed time regardless of the initial condition. Then, a fixed‐time backstepping controller (BSP) is integrated into the ISMC as the nominal controller to realize global fixed‐time convergence. Furthermore, to overcome the singularity problem, a nonsingular fixed‐time sliding surface is designed and integrated into the controller, which is useful for practical application. Finally, the proposed controller is validated for a two‐link robot manipulator with uncertainties and external human forces. The results show that the proposed controller is superior in the sense of both tracking error and convergence time, and at the same time, can comply with human motion in a shared workspace.
FOS: Computer and information sciences, fixed-time convergence, robot manipulator, Automated systems (robots, etc.) in control theory, Systems and Control (eess.SY), Electrical Engineering and Systems Science - Systems and Control, 620, 510, Computer Science - Robotics, Finite-time stability, FOS: Electrical engineering, electronic engineering, information engineering, admittance control, Variable structure systems, physical human-robot collaboration, integral sliding mode control, Robotics (cs.RO)
FOS: Computer and information sciences, fixed-time convergence, robot manipulator, Automated systems (robots, etc.) in control theory, Systems and Control (eess.SY), Electrical Engineering and Systems Science - Systems and Control, 620, 510, Computer Science - Robotics, Finite-time stability, FOS: Electrical engineering, electronic engineering, information engineering, admittance control, Variable structure systems, physical human-robot collaboration, integral sliding mode control, Robotics (cs.RO)
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