Title :
Joint driver and control design for large torque, long arm space remote manipulator
Author :
Guo, Chuangqiang ; Ni, Fenglei ; Sun, Jingting ; Liu, Yechao ; Liu, Hong
Author_Institution :
State Key Lab. of Robot. & Syst., Harbin Inst. of Technol., Harbin, China
Abstract :
This paper presents an overview of the structure and requirements of a ground engineering model for a space remote manipulator system, with long arm and large torque driver capacity. The system consists of a 6 DOFs robot arm composed of six identical modular joints, and a large-error tolerated end effector. A FPGA based joint controller hardware structure is built to form a distributed control scheme of the robot arm, while a fourth-order hybrid controller based on the joint torque feedback is adopted to reduce the influence of joint flexibility, brought by the harmonic drivers and torque sensor, on the control precision. A single-joint control experiment, designed to lift up a load at the tip of a link, about two meters in length, is used to test the ability of trajectory tracking in the gravity field.
Keywords :
distributed control; end effectors; feedback; field programmable gate arrays; position control; sensors; torque control; distributed control scheme; field programmable gate array; fourth-order hybrid controller; harmonic drivers; joint torque feedback; large-error tolerated end effector; long arm capacity; modular joints; single-joint control experiment; space remote manipulator; torque driver capacity; torque sensor; trajectory tracking; Control design; Distributed control; End effectors; Feedback; Field programmable gate arrays; Hardware; Manipulators; Orbital robotics; Robot sensing systems; Torque control; Driver & Control; Modular Joint; Space Robot;
Conference_Titel :
Information and Automation (ICIA), 2010 IEEE International Conference on
Conference_Location :
Harbin
Print_ISBN :
978-1-4244-5701-4
DOI :
10.1109/ICINFA.2010.5512091
