Author ORCID Identifier
https://orcid.org/0000-0003-2341-4962
Advisor Information
Dr. Sara Myers
Location
MBSC Gallery Room 308 - G
Presentation Type
Oral Presentation
Start Date
4-3-2022 2:00 PM
End Date
4-3-2022 3:15 PM
Abstract
Introduction
The passive ankle exoskeleton developed by Collins et al. (2015) reduced the metabolic cost of walking with an actuation-timing of ~16% of stance [1]; however, other actuation timings have not been extensively investigated. Therefore, the purpose of this study was to determine the optimal relationship between actuator-stiffness and actuation-timing for a passive ankle exoskeleton by using musculoskeletal modeling.
Methods
Kinematics and ground reaction forces were recorded while a healthy-young male walked on overground force-plates, and these data were exported to a musculoskeletal modeling software (OpenSim) for simulation. A passive ankle exoskeleton model was designed and integrated with a default OpenSim lower-limb model. A total of 2000 simulations were performed to test all combinations of 20 actuator stiffnesses (5.5-17.5 kN/m) and 10 actuation timings (15-60% stance) across 10 walking steps. The Umberger probe [2] was used to estimate the metabolic rate of each muscle and the integrals of the metabolic rates for all the lower extremity muscles were used to estimate the total metabolic cost of walking.
Results and Discussion
The greatest reduction in metabolic cost (Δ -2.67% ± 0.83%, p
References
[1] Collins et al., “Reducing the energy cost of human walking using an unpowered exoskeleton,” Nature., vol. 522, no. 7555, pp. 212–215, 2015, doi:10.1038/nature14288.
[2] Umberger BR. Stance and swing phase costs in human walking. J R Soc Interface. 2010;7(50):1329-1340. doi:10.1098/rsif.2010.0084
Scheduling Link
1
THE OPTIMAL RELATIONSHIP BETWEEN ACTUATOR STIFFNESS AND ACTUATION TIMING FOR A PASSIVE ANKLE EXOSKELETON: AN OPENSIM SIMULATION
MBSC Gallery Room 308 - G
Introduction
The passive ankle exoskeleton developed by Collins et al. (2015) reduced the metabolic cost of walking with an actuation-timing of ~16% of stance [1]; however, other actuation timings have not been extensively investigated. Therefore, the purpose of this study was to determine the optimal relationship between actuator-stiffness and actuation-timing for a passive ankle exoskeleton by using musculoskeletal modeling.
Methods
Kinematics and ground reaction forces were recorded while a healthy-young male walked on overground force-plates, and these data were exported to a musculoskeletal modeling software (OpenSim) for simulation. A passive ankle exoskeleton model was designed and integrated with a default OpenSim lower-limb model. A total of 2000 simulations were performed to test all combinations of 20 actuator stiffnesses (5.5-17.5 kN/m) and 10 actuation timings (15-60% stance) across 10 walking steps. The Umberger probe [2] was used to estimate the metabolic rate of each muscle and the integrals of the metabolic rates for all the lower extremity muscles were used to estimate the total metabolic cost of walking.
Results and Discussion
The greatest reduction in metabolic cost (Δ -2.67% ± 0.83%, p
References
[1] Collins et al., “Reducing the energy cost of human walking using an unpowered exoskeleton,” Nature., vol. 522, no. 7555, pp. 212–215, 2015, doi:10.1038/nature14288.
[2] Umberger BR. Stance and swing phase costs in human walking. J R Soc Interface. 2010;7(50):1329-1340. doi:10.1098/rsif.2010.0084