Passivity based on energy tank for cartesian impedance control of DLR space robots with floating base and elastic joints

This paper presents a control structure for orbital servicing mission of CEASAR robotic arm developed by German Aerospace Center (DLR). In order to reduce mass the CEASAR arm is equipped with Harmonic-Drives with high ratio which unfortunately lead to high joint elasticity and high motor friction and have to be considered in controller design for successful manipulator in-orbit operations. | Journal of Computer Science and Cybernetics, , (2018), 49–61 DOI PASSIVITY BASED ON ENERGY TANK FOR CARTESIAN IMPEDANCE CONTROL OF DLR SPACE ROBOTS WITH FLOATING BASE AND ELASTIC JOINTS LE TIEN LUC German Aerospace Center (DLR), Institute of Robotics and Mechatronics Abstract. This paper presents a control structure for orbital servicing mission of CEASAR robotic arm developed by German Aerospace Center (DLR). In order to reduce mass the CEASAR arm is equipped with Harmonic-Drives with high ratio which unfortunately lead to high joint elasticity and high motor friction and have to be considered in controller design for successful manipulator in-orbit operations. Therefore, in this control structure, for high tracking control a cascaded position controller based on state feedback control structure with observer-based friction compensation and for safe interaction control with the environment a Cartesian impedance controller is used, which is designed based on using energy tank method to ensure passivity of the controlled system. The proposed control methods are very efficient and practicable. Furthermore, they are very robust with dynamic parameter uncertainties, coupling dynamics, and can simultaneously provide good results in term of the position accuracy and dynamic behavior. Simulation results validate practical effciency of the controllers. Keywords. Impedance control, floating base robots, space robots, flexible joint robots. 1. INTRODUCTION In recent years the use of robots in space has become more and more of interest. With increasing capability of sophisticated autonomy, the robot can be used in such applications as • Exploration of distant planets, • Orbital servicing/repair in low earth orbit or geostationary earth orbit, • De-orbiting of failed satellites, • Constructions of heavy structures (. Space Station, Planetary Bases). . . In this paper the control issues of a space robotic arm .

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