Title :
Dynamic stability of variable stiffness running
Author :
Jun, Jae Yun ; Clark, Jonathan E.
Author_Institution :
Dept. of Mech. Eng., FSU, Tallahassee, FL, USA
Abstract :
Humans and animals adapt their leg impedance during running for both internal(e.g. loading) and external(e.g. surface) changes. In this paper we examine the relationship between leg stiffness and the speed and stability of dynamic legged locomotion. We utilize a torque-driven reduced-order model of running based on a successful family of running robots to show how optimal clock-driven controllers can interact with variably compliant limbs to adapt to changing operating conditions. We show that the leg stiffness adaptation gives, in general, better results than simply optimizing the gait controller and nearly as good as the co-optimization of controller and leg stiffness.
Keywords :
legged locomotion; optimal control; reduced order systems; robot dynamics; stability; dynamic legged locomotion; dynamic stability; gait controller; leg stiffness; optimal clock-driven controller; torque-driven reduced-order model; variable stiffness running; Animals; Clocks; Humans; Leg; Legged locomotion; Optimal control; Reduced order systems; Robots; Stability; Surface impedance;
Conference_Titel :
Robotics and Automation, 2009. ICRA '09. IEEE International Conference on
Conference_Location :
Kobe
Print_ISBN :
978-1-4244-2788-8
Electronic_ISBN :
1050-4729
DOI :
10.1109/ROBOT.2009.5152810
