An Underactuated Active Transfemoral Prosthesis With Series Elastic Actuators Enables Multiple Locomotion Tasks

Ilaria Fagioli; Francesco Lanotte; Tommaso Fiumalbi; Andrea Baldoni; Alessandro Mazzarini; Filippo Dell'agnello; Huseyin Eken; Vito Papapicco; Tommaso Ciapetti; Alessandro Maselli; Claudio Macchi; Sofia Dalmiani; Angelo Davalli; Emanuele Gruppioni; Emilio Trigili; Simona Crea; Nicola Vitiello

doi:10.1109/TRO.2024.3415228

An Underactuated Active Transfemoral Prosthesis With Series Elastic Actuators Enables Multiple Locomotion Tasks

Ilaria Fagioli^*, Francesco Lanotte, Tommaso Fiumalbi, Andrea Baldoni, Alessandro Mazzarini, Filippo Dell'agnello, Huseyin Eken, Vito Papapicco, Tommaso Ciapetti, Alessandro Maselli, Claudio Macchi, Sofia Dalmiani, Angelo Davalli, Emanuele Gruppioni, Emilio Trigili, Simona Crea, Nicola Vitiello

^*Corresponding author for this work

Physical Medicine and Rehabilitation

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

Robotic lower limb prostheses have the power to revolutionize mobility by enhancing gait efficiency and facilitating movement. While several design approaches have been explored to create lightweight and energy-efficient devices, the potential of underactuation remains largely untapped in lower limb prosthetics. Taking inspiration from the natural harmony of walking, in this article, we have developed an innovative active transfemoral prosthesis. By incorporating underactuation, our design uses a single power actuator placed near the knee joint and connected to a differential mechanism to drive both the knee and ankle joints. We conduct comprehensive benchtop tests and evaluate the prosthesis with three individuals who have above-knee amputations, assessing its performance in walking, stair climbing, and transitions between sitting and standing. Our evaluation focuses on gathering position and torque data recorded from sensors integrated into the prosthesis and comparing these measurements to biomechanical data of able-bodied locomotion. Our findings highlight the promise of underactuation in advancing lower limb prosthetics and demonstrate the feasibility of our knee-ankle underactuated design in various tasks, showcasing its ability to replicate natural movement.

Original language	English (US)
Pages (from-to)	3306-3321
Number of pages	16
Journal	IEEE Transactions on Robotics
Volume	40
DOIs	https://doi.org/10.1109/TRO.2024.3415228
State	Published - 2024

Keywords

Powered prostheses
series elastic actuator (SEA)
underactuation
wearable robotics

ASJC Scopus subject areas

Control and Systems Engineering
Computer Science Applications
Electrical and Electronic Engineering

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10.1109/TRO.2024.3415228

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Fagioli, I., Lanotte, F., Fiumalbi, T., Baldoni, A., Mazzarini, A., Dell'agnello, F., Eken, H., Papapicco, V., Ciapetti, T., Maselli, A., Macchi, C., Dalmiani, S., Davalli, A., Gruppioni, E., Trigili, E., Crea, S., & Vitiello, N. (2024). An Underactuated Active Transfemoral Prosthesis With Series Elastic Actuators Enables Multiple Locomotion Tasks. IEEE Transactions on Robotics, 40, 3306-3321. https://doi.org/10.1109/TRO.2024.3415228

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title = "An Underactuated Active Transfemoral Prosthesis With Series Elastic Actuators Enables Multiple Locomotion Tasks",

abstract = "Robotic lower limb prostheses have the power to revolutionize mobility by enhancing gait efficiency and facilitating movement. While several design approaches have been explored to create lightweight and energy-efficient devices, the potential of underactuation remains largely untapped in lower limb prosthetics. Taking inspiration from the natural harmony of walking, in this article, we have developed an innovative active transfemoral prosthesis. By incorporating underactuation, our design uses a single power actuator placed near the knee joint and connected to a differential mechanism to drive both the knee and ankle joints. We conduct comprehensive benchtop tests and evaluate the prosthesis with three individuals who have above-knee amputations, assessing its performance in walking, stair climbing, and transitions between sitting and standing. Our evaluation focuses on gathering position and torque data recorded from sensors integrated into the prosthesis and comparing these measurements to biomechanical data of able-bodied locomotion. Our findings highlight the promise of underactuation in advancing lower limb prosthetics and demonstrate the feasibility of our knee-ankle underactuated design in various tasks, showcasing its ability to replicate natural movement.",

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author = "Ilaria Fagioli and Francesco Lanotte and Tommaso Fiumalbi and Andrea Baldoni and Alessandro Mazzarini and Filippo Dell'agnello and Huseyin Eken and Vito Papapicco and Tommaso Ciapetti and Alessandro Maselli and Claudio Macchi and Sofia Dalmiani and Angelo Davalli and Emanuele Gruppioni and Emilio Trigili and Simona Crea and Nicola Vitiello",

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year = "2024",

doi = "10.1109/TRO.2024.3415228",

language = "English (US)",

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Fagioli, I, Lanotte, F, Fiumalbi, T, Baldoni, A, Mazzarini, A, Dell'agnello, F, Eken, H, Papapicco, V, Ciapetti, T, Maselli, A, Macchi, C, Dalmiani, S, Davalli, A, Gruppioni, E, Trigili, E, Crea, S & Vitiello, N 2024, 'An Underactuated Active Transfemoral Prosthesis With Series Elastic Actuators Enables Multiple Locomotion Tasks', IEEE Transactions on Robotics, vol. 40, pp. 3306-3321. https://doi.org/10.1109/TRO.2024.3415228

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T1 - An Underactuated Active Transfemoral Prosthesis With Series Elastic Actuators Enables Multiple Locomotion Tasks

AU - Fagioli, Ilaria

AU - Lanotte, Francesco

AU - Fiumalbi, Tommaso

AU - Baldoni, Andrea

AU - Mazzarini, Alessandro

AU - Dell'agnello, Filippo

AU - Eken, Huseyin

AU - Papapicco, Vito

AU - Ciapetti, Tommaso

AU - Maselli, Alessandro

AU - Macchi, Claudio

AU - Dalmiani, Sofia

AU - Davalli, Angelo

AU - Gruppioni, Emanuele

AU - Trigili, Emilio

AU - Crea, Simona

AU - Vitiello, Nicola

PY - 2024

Y1 - 2024

N2 - Robotic lower limb prostheses have the power to revolutionize mobility by enhancing gait efficiency and facilitating movement. While several design approaches have been explored to create lightweight and energy-efficient devices, the potential of underactuation remains largely untapped in lower limb prosthetics. Taking inspiration from the natural harmony of walking, in this article, we have developed an innovative active transfemoral prosthesis. By incorporating underactuation, our design uses a single power actuator placed near the knee joint and connected to a differential mechanism to drive both the knee and ankle joints. We conduct comprehensive benchtop tests and evaluate the prosthesis with three individuals who have above-knee amputations, assessing its performance in walking, stair climbing, and transitions between sitting and standing. Our evaluation focuses on gathering position and torque data recorded from sensors integrated into the prosthesis and comparing these measurements to biomechanical data of able-bodied locomotion. Our findings highlight the promise of underactuation in advancing lower limb prosthetics and demonstrate the feasibility of our knee-ankle underactuated design in various tasks, showcasing its ability to replicate natural movement.

AB - Robotic lower limb prostheses have the power to revolutionize mobility by enhancing gait efficiency and facilitating movement. While several design approaches have been explored to create lightweight and energy-efficient devices, the potential of underactuation remains largely untapped in lower limb prosthetics. Taking inspiration from the natural harmony of walking, in this article, we have developed an innovative active transfemoral prosthesis. By incorporating underactuation, our design uses a single power actuator placed near the knee joint and connected to a differential mechanism to drive both the knee and ankle joints. We conduct comprehensive benchtop tests and evaluate the prosthesis with three individuals who have above-knee amputations, assessing its performance in walking, stair climbing, and transitions between sitting and standing. Our evaluation focuses on gathering position and torque data recorded from sensors integrated into the prosthesis and comparing these measurements to biomechanical data of able-bodied locomotion. Our findings highlight the promise of underactuation in advancing lower limb prosthetics and demonstrate the feasibility of our knee-ankle underactuated design in various tasks, showcasing its ability to replicate natural movement.

KW - Powered prostheses

KW - series elastic actuator (SEA)

KW - underactuation

KW - wearable robotics

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JF - IEEE Transactions on Robotics

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An Underactuated Active Transfemoral Prosthesis With Series Elastic Actuators Enables Multiple Locomotion Tasks

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Keywords

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