The spring stiffness profile within a passive, full-leg exoskeleton affects lower-limb joint mechanics while hopping. Journal Article uri icon

Overview

abstract

  • Passive, full-leg exoskeletons that act in parallel with the legs can reduce the metabolic power of bouncing gaits like hopping. However, the magnitude of metabolic power reduction depends on the spring stiffness profile of the exoskeleton and is presumably affected by how users adapt their lower-limb joint mechanics. We determined the effects of using a passive, full-leg exoskeleton with degressive (DG), linear (LN) and progressive (PG) stiffness springs on lower-limb joint kinematics and kinetics during stationary, bilateral hopping at 2.4 Hz. We found that the use of a passive, full-leg exoskeleton primarily reduced the muscle-tendon units (MTUs) contribution to overall joint moment and power at the ankle, followed by the knee, due to the average exoskeleton moment arm around each joint. The greatest reductions occurred with DG springs, followed by LN and PG stiffness springs, probably due to differences in elastic energy return. Moreover, the relative distribution of positive joint power remained unchanged when using a passive, full-leg exoskeleton compared with unassisted hopping. Passive, full-leg exoskeletons simultaneously assist multiple lower-limb joints and future assistive devices should consider the effects of spring stiffness profile in their design.

publication date

  • March 1, 2024

has restriction

  • gold

Date in CU Experts

  • March 22, 2024 5:15 AM

Full Author List

  • Allen SP; Grabowski AM

author count

  • 2

Other Profiles

International Standard Serial Number (ISSN)

  • 2054-5703

Additional Document Info

start page

  • 231449

volume

  • 11

issue

  • 3