Powered ankle-foot prosthesis

Author

Au, Samuel K. ; Herr, Hugh M.

Author_Institution

Biomechatronics Group, MIT Media Lab., Cambridge, MA

Volume

15

Issue

3

fYear

2008

fDate

9/1/2008 12:00:00 AM

Firstpage

52

Lastpage

59

Abstract

The minimum level of series compliance that adequately protects the transmission from damage during foot collision fails to satisfy bandwidth requirements. As a resolution to this difficulty, parallel motor elasticity is used to lower the forces borne by the SEA, enhancing system force bandwidth. To minimize prosthesis cost of transport (COT) and motor or transmission size, we select a parallel stiffness that supplies the necessary ankle stiffness during early stance period dorsiflexion, eliminating the need for SEA during that gait phase. In future investigations, we hope to apply the ankle-foot design to robotic, orthotic, and exoskeletal applications. In the design of biomimetic ankle-foot systems, we feel both series and parallel motor elasticity are of paramount importance.

Keywords

elasticity; electric motors; prosthetics; ankle stiffness; cost of transport; early stance period dorsiflexion; foot collision; parallel motor elasticity; parallel stiffness; powered ankle-foot prosthesis; Actuators; Biomimetics; Elasticity; Humans; Impedance; Knee; Leg; Legged locomotion; Muscles; Prosthetics; amputee gait; impedance control; parallel elasticity; powered ankle-foot prosthesis; series elasticity;

fLanguage

English

Journal_Title

Robotics & Automation Magazine, IEEE

Publisher

ieee

ISSN

1070-9932

Type

jour

DOI

10.1109/MRA.2008.927697

Filename

4624583