Human-in-the-Loop Optimization of Hip Exoskeleton Assistance During Stair Climbing

Objective: This study applies human-in-the-loop optimization to identify optimal hip exoskeleton assistance patterns for stair climbing. Methods: Ten participants underwent optimization to individualize hip flexion and extension assistance, followed by a validation comparing optimized assistance (OP...

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Bibliographic Details
Published inIEEE transactions on biomedical engineering Vol. 72; no. 7; pp. 2147 - 2156
Main Authors Park, Dongho, An, Jimin, Lee, Dawit, Kang, Inseung, Young, Aaron J.
Format Journal Article
LanguageEnglish
Published United States IEEE 01.07.2025
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Adult
Bayesian optimization
Biomechanical Phenomena - physiology
Climbing
Convergence
Costs
Exoskeleton
Exoskeleton Device
Exoskeletons
Female
Flexible printed circuits
Hip
Hip - physiology
hip exoskeleton
human-in-the-loop optimization
Humans
Legged locomotion
Male
metabolic cost
Metabolic rate
Metabolism
Optimal control
Optimization
Parameter identification
Pelvis
personalized assistance
stair climbing
Stair Climbing - physiology
Stairs
Statistical analysis
Timing
Torque
Young Adult
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Summary:Objective: This study applies human-in-the-loop optimization to identify optimal hip exoskeleton assistance patterns for stair climbing. Methods: Ten participants underwent optimization to individualize hip flexion and extension assistance, followed by a validation comparing optimized assistance (OPT) to biological hip moment-based assistance (BIO), no assistance (No-Assist), and no exoskeleton (No-Exo) conditions. Results: OPT reduced metabolic cost by 4.5% compared to No-Exo, 11.44% compared to No-Assist, and 5.02% compared to BIO, demonstrating the effectiveness of the optimization approach. Statistical analysis revealed distinct characteristics in optimal assistance timing and magnitude that deviated systematically from biological hip moment patterns. Compared to BIO, OPT exhibited later peak flexion timing (76.4 <inline-formula><tex-math notation="LaTeX">\pm</tex-math></inline-formula> 3.7% vs 65.0%), shorter flexion duration (29.2 <inline-formula><tex-math notation="LaTeX">\pm</tex-math></inline-formula> 3.6% vs 40.0%), later peak extension timing (26.7 <inline-formula><tex-math notation="LaTeX">\pm</tex-math></inline-formula> 3.8% vs 20.0% of gait cycle), and higher peak flexion magnitude (11.1 <inline-formula><tex-math notation="LaTeX">\pm</tex-math></inline-formula> 1.5 Nm vs 10.0 Nm). While individual optimal assistance profiles varied across participants, comparison between individually optimized parameters and the best subject-independent parameters identified through post-hoc analysis showed consistency. On average, metabolic rate convergence was achieved after 18 iterations, while most exoskeleton control parameters did not reach our convergence criteria within 20 iterations. Conclusion: These findings demonstrate that human-in-the-loop optimization can effectively identify task-specific assistance patterns for stair climbing, while the consistency between individual and subject-independent parameters suggests the potential for developing generalized assistance strategies. The systematic differences between optimized and biological moment-based assistance underscore the fundamental distinctions between biological torque-based control and optimal control for exoskeleton assistance.
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ISSN:0018-9294
1558-2531
1558-2531
DOI:10.1109/TBME.2025.3536516