Recent advancements in powered lower limb prostheses have appeased several difficulties faced by lower limb amputees by using a series-elastic actuator (SEA) to provide powered sagittal plane flexion. Unfortunately, these devices are currently unable to provide both powered sagittal plane flexion and two degrees of freedom (2-DOF) at the ankle, removing the ankle’s capacity to invert/evert, thus severely limiting terrain adaption capabilities and user comfort. The developed 2-DOF ankle system in this paper allows both powered flexion in the sagittal plane and passive rotation in the frontal plane; an SEA emulates the biomechanics of the gastrocnemius and Achilles tendon for flexion while a novel universal-joint system provides the 2-DOF. Several studies were undertaken to thoroughly characterize the capabilities of the device. Under both level- and sloped-ground conditions, ankle torque and kinematic data were obtained by using force-plates and a motion capture system. The device was found to be fully capable of providing powered sagittal plane motion and torque very close to that of a biological ankle while simultaneously being able to adapt to sloped terrain by undergoing frontal plane motion, thus providing 2-DOF at the ankle. These findings demonstrate that the device presented in this paper poses radical improvements to powered prosthetic ankle-foot device (PAFD) design.
Skip Nav Destination
Article navigation
August 2019
Research-Article
Biologically Inspired Design and Development of a Variable Stiffness Powered Ankle-Foot Prosthesis
Alexander Agboola-Dobson,
Alexander Agboola-Dobson
School of Mechanical,
Aerospace and Civil Engineering,
Manchester M13 9PL,
e-mail: alex-dobson@outlook.com
Aerospace and Civil Engineering,
The University of Manchester
,Manchester M13 9PL,
UK
e-mail: alex-dobson@outlook.com
Search for other works by this author on:
Guowu Wei,
Guowu Wei
1
Mem. ASME
School of Computing,
Science and Engineering,
Salford M5 4WT,
e-mail: g.wei@salford.ac.uk
School of Computing,
Science and Engineering,
University of Salford
,Salford M5 4WT,
UK
e-mail: g.wei@salford.ac.uk
1Corresponding authors.
Search for other works by this author on:
Lei Ren
Lei Ren
1
School of Mechanical,
Aerospace and Civil Engineering,
Manchester M13 9PL,
e-mail: lei.ren@manchester.ac.uk
Aerospace and Civil Engineering,
The University of Manchester
,Manchester M13 9PL,
UK
e-mail: lei.ren@manchester.ac.uk
1Corresponding authors.
Search for other works by this author on:
Alexander Agboola-Dobson
School of Mechanical,
Aerospace and Civil Engineering,
Manchester M13 9PL,
e-mail: alex-dobson@outlook.com
Aerospace and Civil Engineering,
The University of Manchester
,Manchester M13 9PL,
UK
e-mail: alex-dobson@outlook.com
Guowu Wei
Mem. ASME
School of Computing,
Science and Engineering,
Salford M5 4WT,
e-mail: g.wei@salford.ac.uk
School of Computing,
Science and Engineering,
University of Salford
,Salford M5 4WT,
UK
e-mail: g.wei@salford.ac.uk
Lei Ren
School of Mechanical,
Aerospace and Civil Engineering,
Manchester M13 9PL,
e-mail: lei.ren@manchester.ac.uk
Aerospace and Civil Engineering,
The University of Manchester
,Manchester M13 9PL,
UK
e-mail: lei.ren@manchester.ac.uk
1Corresponding authors.
Contributed by the Mechanisms and Robotics Committee of ASME for publication in the Journal of Mechanisms and Robotics. Manuscript received July 2, 2018; final manuscript received April 13, 2019; published online May 17, 2019. Assoc. Editor: Pinhas Ben-Tzvi.
J. Mechanisms Robotics. Aug 2019, 11(4): 041012 (15 pages)
Published Online: May 17, 2019
Article history
Received:
July 2, 2018
Revision Received:
April 13, 2019
Accepted:
April 16, 2019
Citation
Agboola-Dobson, A., Wei, G., and Ren, L. (May 17, 2019). "Biologically Inspired Design and Development of a Variable Stiffness Powered Ankle-Foot Prosthesis." ASME. J. Mechanisms Robotics. August 2019; 11(4): 041012. https://doi.org/10.1115/1.4043603
Download citation file:
Get Email Alerts
Design of Rolling Motion for Snake-like Robots using Center-of-Gravity (COG) Shift
J. Mechanisms Robotics
Modelling and Control of Cable Driven Exoskeleton for Arm Rehabilitation
J. Mechanisms Robotics
Design of an underactuated, flexure-based gripper, actuated through a push-pull flexure
J. Mechanisms Robotics
Related Articles
The Effects of the Inertial Properties of Above-Knee Prostheses on Optimal Stiffness, Damping, and Engagement Parameters of Passive Prosthetic Knees
J Biomech Eng (December,2016)
A Compact, Modular Series Elastic Actuator
J. Mechanisms Robotics (August,2016)
A Fully Compliant Homokinetic Coupling
J. Mech. Des (January,2018)
On the Technological Instantiation of a Biomimetic Leg Concept for Agile Quadrupedal Locomotion
J. Mechanisms Robotics (August,2015)
Related Proceedings Papers
Related Chapters
QP Based Encoder Feedback Control
Robot Manipulator Redundancy Resolution
Accuracy of an Axis
Mechanics of Accuracy in Engineering Design of Machines and Robots Volume I: Nominal Functioning and Geometric Accuracy
Fault-Tolerant Control of Sensors and Actuators Applied to Wind Energy Systems
Electrical and Mechanical Fault Diagnosis in Wind Energy Conversion Systems