Anti-Dead-Zone Integral Sliding Control and Active Vibration Suppression of a Free-floating Space Robot with Elastic Base and Flexible Links

Under the conditions of joint torque output dead-zone and external disturbance,the trajectory tracking and vibration suppression for a free-floating space robot( FFSR) system with elastic base and flexible links were discussed. First,using the Lagrange equation of the second kind,the dynamic model of the system was derived. Second,utilizing singular perturbation theory,a slow subsystem describing the rigid motion and a fast subsystem corresponding to flexible vibration were obtained. For the slow subsystem,when the width of deadzone is uncertain,a dead-zone pre-compensator was designed to eliminate the impact of joint torque output dead-zone,and an integral sliding mode neural network control was proposed. The integral sliding mode term can reduce the steady state error. For the fast subsystem,an optimal linear quadratic regulator( LQR) controller was adopted to damp out the vibration of the flexible links and elastic base simultaneously. Finally,computer simulations show the effectiveness of the compound control method.