Title :
Optimal gait primitives for dynamic bipedal locomotion
Author :
Lim, Bokman ; Lee, Jusuk ; Kim, Joohyung ; Lee, Minhyung ; Kwak, Hoseong ; Kwon, Sunggu ; Lee, Heekuk ; Kwon, Woong ; Roh, Kyungshik
Author_Institution :
Samsung Adv. Inst. of Technol., Yongin, South Korea
Abstract :
This paper presents a framework to generate dynamic walking for biped robots. A set of self-stable gait primitives is first constructed. It is done by 1) representing parametric gait primitives, 2) utilizing state-dependent torque control, and 3) doing numerical optimization that takes into account the complex multi-body dynamics with frictional contact forces. Dynamic walking to follow the arbitrary path including a curve is then generated online via sequentially composing primitive motions. Results show that dynamic gaits are humanlike and efficient compared to the conventional knee bent walkers. Our proposed method is applied to a torque-controlled, human-sized biped robot platform, `Roboray´ which is cable-driven partially for joint compliance. Following a discussion on robot design and control, experimental results are also reported.
Keywords :
humanoid robots; legged locomotion; robot dynamics; torque control; Roboray; dynamic bipedal locomotion; dynamic walking; frictional contact force; human-sized biped robot platform; multibody dynamics; numerical optimization; optimal gait primitives; parametric gait primitive; robot design; self-stable gait primitive; state-dependent torque control; torque-controlled biped robot platform; Dynamics; Heuristic algorithms; Hip; Joints; Legged locomotion; Optimization;
Conference_Titel :
Intelligent Robots and Systems (IROS), 2012 IEEE/RSJ International Conference on
Conference_Location :
Vilamoura
Print_ISBN :
978-1-4673-1737-5
DOI :
10.1109/IROS.2012.6385753
