Title :
Balancing control of a biped robot
Author :
Kim, Joohyung ; Kwak, Hoseong ; Lee, Heekuk ; Seo, Keehong ; Lim, Bokman ; Lee, Minhyung ; Lee, Jusuk ; Roh, Kyungsik
Author_Institution :
Samsung Adv. Inst. of Technol. (SAIT), Samsung Electron. Co., Ltd., Yongin, South Korea
Abstract :
We propose a balancing control framework for a torque-controlled biped robot, Roboray. Roboray has two 6 DOF legs and torque sensors are integrated at all the leg joints. It has a new cable-driven joint module as a pitch joint drive, which is highly back-drivable and elastic. Using these hardware characteristics, we propose a new balancing control algorithm. This algorithm is the combination of gravity compensation, virtual gravity control and damping control. A friction compensation technique is also introduced in order to eliminate the nonlinearity of damping and to improve the performance of torque tracking. Our proposed method is applied to a simple inverted pendulum system and Roboray. Experimental results show that these two system keep their balance when they are pushed slightly.
Keywords :
control nonlinearities; damping; elasticity; friction; gravity; humanoid robots; legged locomotion; mechanical stability; nonlinear control systems; pendulums; sensors; torque control; 6 DOF leg joints; Roboray; back-drivability; balancing control framework; cable-driven joint module; damping control; damping nonlinearity elimination; elasticity; friction compensation technique; gravity compensation; hardware characteristics; inverted pendulum system; pitch joint drive; torque sensors; torque tracking performance improvement; torque-controlled biped robot; virtual gravity control; Friction; Gravity; Joints; Legged locomotion; Mathematical model; Torque; Humanoid; balancing control; torque control; virtual gravity;
Conference_Titel :
Systems, Man, and Cybernetics (SMC), 2012 IEEE International Conference on
Conference_Location :
Seoul
Print_ISBN :
978-1-4673-1713-9
Electronic_ISBN :
978-1-4673-1712-2
DOI :
10.1109/ICSMC.2012.6378165
