Title :
Investigating human balance using a robotic motion platform
Author :
Huryn, T.P. ; Luu, B.L. ; Van der Loos, H.F.M. ; Blouin, J.S. ; Croft, E.A.
Author_Institution :
Mech. Eng. Dept., Univ. of British Columbia, Vancouver, CA, USA
Abstract :
We present the system design for a novel robotic balance simulator that enables the investigation of the balance mechanisms involved in natural human standing. Our system allows for complete control of task dynamics to mimic normal standing while avoiding the pitfalls associated with applying external perturbations. The system enables subjects to balance themselves according to a programmable physical model of an inverted pendulum. Subjects were able to balance the system, and results show that the load stiffness curves approximate those of normal human standing to within 20.1 ± 9.7% (S.D.). Differences were within the range expected from control loop delay, reduced ankle motion, and approximations inherent to the inverted pendulum model.
Keywords :
motion control; nonlinear control systems; pendulums; robot dynamics; control loop delay; human balance; inverted pendulum; load stiffness curve; robotic balance simulator; robotic motion platform; task dynamics; Biological system modeling; Control systems; Humans; Legged locomotion; Medical control systems; Muscles; Robot motion; Robot sensing systems; Robotics and automation; Spinal cord injury;
Conference_Titel :
Robotics and Automation (ICRA), 2010 IEEE International Conference on
Conference_Location :
Anchorage, AK
Print_ISBN :
978-1-4244-5038-1
Electronic_ISBN :
1050-4729
DOI :
10.1109/ROBOT.2010.5509378
