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Main Authors: Leem, Geonho, Lee, Jaedong, Lee, Jehee, Song, Seungmoon, Won, Jungdam
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2601.22550
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author Leem, Geonho
Lee, Jaedong
Lee, Jehee
Song, Seungmoon
Won, Jungdam
author_facet Leem, Geonho
Lee, Jaedong
Lee, Jehee
Song, Seungmoon
Won, Jungdam
contents Exoskeletons show great promise for enhancing mobility, but providing appropriate assistance remains challenging due to the complexity of human adaptation to external forces. Current state-of-the-art approaches for optimizing exoskeleton controllers require extensive human experiments in which participants must walk for hours, creating a paradox: those who could benefit most from exoskeleton assistance, such as individuals with mobility impairments, are rarely able to participate in such demanding procedures. We present Exo-plore, a simulation framework that combines neuromechanical simulation with deep reinforcement learning to optimize hip exoskeleton assistance without requiring real human experiments. Exo-plore can (1) generate realistic gait data that captures human adaptation to assistive forces, (2) produce reliable optimization results despite the stochastic nature of human gait, and (3) generalize to pathological gaits, showing strong linear relationships between pathology severity and optimal assistance.
format Preprint
id arxiv_https___arxiv_org_abs_2601_22550
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Exo-Plore: Exploring Exoskeleton Control Space through Human-aligned Simulation
Leem, Geonho
Lee, Jaedong
Lee, Jehee
Song, Seungmoon
Won, Jungdam
Robotics
Graphics
Machine Learning
Exoskeletons show great promise for enhancing mobility, but providing appropriate assistance remains challenging due to the complexity of human adaptation to external forces. Current state-of-the-art approaches for optimizing exoskeleton controllers require extensive human experiments in which participants must walk for hours, creating a paradox: those who could benefit most from exoskeleton assistance, such as individuals with mobility impairments, are rarely able to participate in such demanding procedures. We present Exo-plore, a simulation framework that combines neuromechanical simulation with deep reinforcement learning to optimize hip exoskeleton assistance without requiring real human experiments. Exo-plore can (1) generate realistic gait data that captures human adaptation to assistive forces, (2) produce reliable optimization results despite the stochastic nature of human gait, and (3) generalize to pathological gaits, showing strong linear relationships between pathology severity and optimal assistance.
title Exo-Plore: Exploring Exoskeleton Control Space through Human-aligned Simulation
topic Robotics
Graphics
Machine Learning
url https://arxiv.org/abs/2601.22550