Physical interface dynamics alter how robotic exosuits augment human movement: implications for optimizing wearable assistive devices

Wearable assistive devices have demonstrated the potential to improve mobility outcomes for individuals with disabilities, and to augment healthy human performance; however, these benefits depend on how effectively power is transmitted from the device to the human user. Quantifying and understanding...

Full description

Saved in:
Bibliographic Details
Published in:Journal of neuroengineering and rehabilitation 2017-05, Vol.14 (1), p.40-40, Article 40
Main Authors: Yandell, Matthew B, Quinlivan, Brendan T, Popov, Dmitry, Walsh, Conor, Zelik, Karl E
Format: Article
Language:English
Subjects:
Absorption
Ankle
Augmentation
Automation
Biomechanics
Brain-Computer Interfaces
Deformation
Design analysis
Design improvements
Devices
Disabilities
Displacement
Dynamics
Energy absorption
Estimation
Exoskeleton
Exoskeleton Device
Experiments
Health aspects
Human body
Human mechanics
Human motion
Human performance
Humans
Interfaces
International conferences
Joint kinetics
Load
Metabolism
Methods
Mobility
Motion
Motion capture
Movement
Optimization
People with disabilities
Phases
Power transfer
Pressure distribution
Rehabilitation
Robot control
Robotics
Robotics - instrumentation
Robots
Soft tissue
Soft tissues
Textiles
Tissues
Unloading
Walking
Wearable robot
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Wearable assistive devices have demonstrated the potential to improve mobility outcomes for individuals with disabilities, and to augment healthy human performance; however, these benefits depend on how effectively power is transmitted from the device to the human user. Quantifying and understanding this power transmission is challenging due to complex human-device interface dynamics that occur as biological tissues and physical interface materials deform and displace under load, absorbing and returning power. Here we introduce a new methodology for quickly estimating interface power dynamics during movement tasks using common motion capture and force measurements, and then apply this method to quantify how a soft robotic ankle exosuit interacts with and transfers power to the human body during walking. We partition exosuit end-effector power (i.e., power output from the device) into power that augments ankle plantarflexion (termed augmentation power) vs. power that goes into deformation and motion of interface materials and underlying soft tissues (termed interface power). We provide empirical evidence of how human-exosuit interfaces absorb and return energy, reshaping exosuit-to-human power flow and resulting in three key consequences: (i) During exosuit loading (as applied forces increased), about 55% of exosuit end-effector power was absorbed into the interfaces. (ii) However, during subsequent exosuit unloading (as applied forces decreased) most of the absorbed interface power was returned viscoelastically. Consequently, the majority (about 75%) of exosuit end-effector work over each stride contributed to augmenting ankle plantarflexion. (iii) Ankle augmentation power (and work) was delayed relative to exosuit end-effector power, due to these interface energy absorption and return dynamics. Our findings elucidate the complexities of human-exosuit interface dynamics during transmission of power from assistive devices to the human body, and provide insight into improving the design and control of wearable robots. We conclude that in order to optimize the performance of wearable assistive devices it is important, throughout design and evaluation phases, to account for human-device interface dynamics that affect power transmission and thus human augmentation benefits.
ISSN:1743-0003
1743-0003
DOI:10.1186/s12984-017-0247-9