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Optimal Energy Shaping Control for a Backdrivable Hip Exoskeleton

Overview
Journal Proc Am Control Conf
Date 2023 Oct 4
PMID 37790804
Authors
Jiefu Zhang
Jianping Lin
Vamsi Peddinti
Robert D Gregg
Affiliations
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Abstract

Task-dependent controllers widely used in exoskeletons track predefined trajectories, which overly constrain the volitional motion of individuals with remnant voluntary mobility. Energy shaping, on the other hand, provides task-invariant assistance by altering the human body's dynamic characteristics in the closed loop. While human-exoskeleton systems are often modeled using Euler-Lagrange equations, in our previous work we modeled the system as a port-controlled-Hamiltonian system, and a task-invariant controller was designed for a knee-ankle exoskeleton using interconnection-damping assignment passivity-based control. In this paper, we extend this framework to design a controller for a backdrivable hip exoskeleton to assist multiple tasks. A set of basis functions that contains information of kinematics is selected and corresponding coefficients are optimized, which allows the controller to provide torque that fits normative human torque for different activities of daily life. Human-subject experiments with two able-bodied subjects demonstrated the controller's capability to reduce muscle effort across different tasks.

Citing Articles

A Modular Framework for Task-Agnostic, Energy Shaping Control of Lower Limb Exoskeletons.

Lin J, Thomas G, Divekar N, Peddinti V, Gregg R IEEE Trans Control Syst Technol. 2024; 32(6):2359-2375.

PMID: 39474032 PMC: 11513588. DOI: 10.1109/tcst.2024.3429908.

Improving Task-Agnostic Energy Shaping Control of Powered Exoskeletons with Task/Gait Classification.

Lin J, Gregg R, Shull P IEEE Robot Autom Lett. 2024; 9(8):6848-6855.

PMID: 39346114 PMC: 11426205. DOI: 10.1109/lra.2024.3414259.

Optimal Energy Shaping Control for a Backdrivable Hip Exoskeleton.

Zhang J, Lin J, Peddinti V, Gregg R Proc Am Control Conf. 2023; 2023:2065-2070.

PMID: 37790804 PMC: 10544752. DOI: 10.23919/acc55779.2023.10155839.

References
1.
Neumann D . Kinesiology of the hip: a focus on muscular actions. J Orthop Sports Phys Ther. 2010; 40(2):82-94. DOI: 10.2519/jospt.2010.3025. View
2.
Camargo J, Ramanathan A, Flanagan W, Young A . A comprehensive, open-source dataset of lower limb biomechanics in multiple conditions of stairs, ramps, and level-ground ambulation and transitions. J Biomech. 2021; 119:110320. DOI: 10.1016/j.jbiomech.2021.110320. View
3.
Lv G, Zhu H, Gregg R . On the Design and Control of Highly Backdrivable Lower-Limb Exoskeletons: A Discussion of Past and Ongoing Work. IEEE Control Syst. 2019; 38(6):88-113. PMC: 6309856. DOI: 10.1109/MCS.2018.2866605. View
4.
Baud R, Manzoori A, Ijspeert A, Bouri M . Review of control strategies for lower-limb exoskeletons to assist gait. J Neuroeng Rehabil. 2021; 18(1):119. PMC: 8314580. DOI: 10.1186/s12984-021-00906-3. View
5.
Lin J, Divekar N, Thomas G, Gregg R . Optimally Biomimetic Passivity-Based Control of a Lower-Limb Exoskeleton Over the Primary Activities of Daily Life. IEEE Open J Control Syst. 2022; 1:15-28. PMC: 9170045. View