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Hauptverfasser: Tang, Chenyu, Zhu, Yu, Mallah, Josée, Yi, Wentian, Jin, Luyao, Zhang, Zibo, Wang, Shengbo, Xu, Muzi, Shen, Ming, Or, Calvin Kalun, Gao, Shuo, Bai, Shaoping, Occhipinti, Luigi G.
Format: Preprint
Veröffentlicht: 2025
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Online-Zugang:https://arxiv.org/abs/2508.12157
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author Tang, Chenyu
Zhu, Yu
Mallah, Josée
Yi, Wentian
Jin, Luyao
Zhang, Zibo
Wang, Shengbo
Xu, Muzi
Shen, Ming
Or, Calvin Kalun
Gao, Shuo
Bai, Shaoping
Occhipinti, Luigi G.
author_facet Tang, Chenyu
Zhu, Yu
Mallah, Josée
Yi, Wentian
Jin, Luyao
Zhang, Zibo
Wang, Shengbo
Xu, Muzi
Shen, Ming
Or, Calvin Kalun
Gao, Shuo
Bai, Shaoping
Occhipinti, Luigi G.
contents Wearable exoskeletons hold transformative promise for restoring mobility across diverse users with muscular weakness or other impairments. However, their translation beyond laboratory environments remains limited by sensing systems that capture movement but not underlying physiology. Here, we present a soft, lightweight smart leg sleeve that achieves anatomically aligned, layered multimodal sensing by integrating textile-based surface electromyography (sEMG) electrodes, ultrasensitive textile strain sensors, and inertial measurement units (IMUs). Each sensing modality targets a distinct physiological layer: IMUs track joint kinematics at the skeletal level, sEMG monitors muscle activation at the muscular level, and strain sensors detect skin deformation at the cutaneous level. Together, these sensors provide real-time perception to support three core objectives: controlling personalized assistance, optimizing user effort, and safeguarding against injury risks. The system is skin-conformal, mechanically compliant, and seamlessly integrated with a custom exoskeleton ($<20$~g total sensor and electronics weight). We demonstrate: (1) accurate ankle joint moment estimation (RMSE = 0.13~Nm/kg), (2) real-time classification of metabolic trends (accuracy = 97.1\%), and (3) injury risk detection within 100~ms (recall = 0.96), all validated on unseen users using a leave-one-subject-out protocol. This work establishes a physiology-aligned sensing architecture that reframes exoskeleton perception from motion tracking to real-time physiological decoding, offering a pathway towards intelligent, adaptive, and personalized wearable robotics.
format Preprint
id arxiv_https___arxiv_org_abs_2508_12157
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Physiology-informed layered sensing for intelligent human-exoskeleton interaction
Tang, Chenyu
Zhu, Yu
Mallah, Josée
Yi, Wentian
Jin, Luyao
Zhang, Zibo
Wang, Shengbo
Xu, Muzi
Shen, Ming
Or, Calvin Kalun
Gao, Shuo
Bai, Shaoping
Occhipinti, Luigi G.
Systems and Control
Wearable exoskeletons hold transformative promise for restoring mobility across diverse users with muscular weakness or other impairments. However, their translation beyond laboratory environments remains limited by sensing systems that capture movement but not underlying physiology. Here, we present a soft, lightweight smart leg sleeve that achieves anatomically aligned, layered multimodal sensing by integrating textile-based surface electromyography (sEMG) electrodes, ultrasensitive textile strain sensors, and inertial measurement units (IMUs). Each sensing modality targets a distinct physiological layer: IMUs track joint kinematics at the skeletal level, sEMG monitors muscle activation at the muscular level, and strain sensors detect skin deformation at the cutaneous level. Together, these sensors provide real-time perception to support three core objectives: controlling personalized assistance, optimizing user effort, and safeguarding against injury risks. The system is skin-conformal, mechanically compliant, and seamlessly integrated with a custom exoskeleton ($<20$~g total sensor and electronics weight). We demonstrate: (1) accurate ankle joint moment estimation (RMSE = 0.13~Nm/kg), (2) real-time classification of metabolic trends (accuracy = 97.1\%), and (3) injury risk detection within 100~ms (recall = 0.96), all validated on unseen users using a leave-one-subject-out protocol. This work establishes a physiology-aligned sensing architecture that reframes exoskeleton perception from motion tracking to real-time physiological decoding, offering a pathway towards intelligent, adaptive, and personalized wearable robotics.
title Physiology-informed layered sensing for intelligent human-exoskeleton interaction
topic Systems and Control
url https://arxiv.org/abs/2508.12157