A control theoretic approach to robot-assisted locomotor therapy

Author

Gregg, Robert D. ; Bretl, T.W. ; Spong, Mark W.

fYear

2010

fDate

15-17 Dec. 2010

Firstpage

1679

Lastpage

1686

Abstract

This paper proposes a control theoretic strategy for human walking gait assistance based on underactuated potential energy shaping. We design a simple control law that lessens the perceived weight of the patient´s center of mass through a robotic ankle-foot orthosis (AFO) with one actuated degree-of-freedom. We then adopt a passive “compass-gait” bipedal walker as an implicit model of human locomotor behavior, which we simulate to draw beneficial implications for rehabilitation such as energy regulation, improved stability, and progressive training by Lyapunov funneling. Given current challenges in developing effective robot-assisted locomotor therapies, this paper offers a novel systematic approach to control strategy design for gait training and at-home assistance.

Keywords

Lyapunov methods; gait analysis; legged locomotion; medical robotics; orthotics; Lyapunov funneling; at-home assistance; control strategy design; control theoretic strategy; gait training; human locomotor behavior; human walking gait assistance; passive compass-gait bipedal walker; robot-assisted locomotor therapy; robotic ankle-foot orthosis; underactuated potential energy shaping; Angular velocity; Biological system modeling; Hip;

fLanguage

English

Publisher

ieee

Conference_Titel

Decision and Control (CDC), 2010 49th IEEE Conference on

Conference_Location

Atlanta, GA

ISSN

0743-1546

Print_ISBN

978-1-4244-7745-6

Type

conf

DOI

10.1109/CDC.2010.5716929

Filename

5716929