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Autori principali: Zhu, Zenan, Chen, Wenxi, Kao, Pei-Chun, Clark, Janelle, Behnke, Lily, Kramer-Bottiglio, Rebecca, Yanco, Holly, Gu, Yan
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2508.02930
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author Zhu, Zenan
Chen, Wenxi
Kao, Pei-Chun
Clark, Janelle
Behnke, Lily
Kramer-Bottiglio, Rebecca
Yanco, Holly
Gu, Yan
author_facet Zhu, Zenan
Chen, Wenxi
Kao, Pei-Chun
Clark, Janelle
Behnke, Lily
Kramer-Bottiglio, Rebecca
Yanco, Holly
Gu, Yan
contents This letter presents a model-agnostic meta-learning (MAML) based framework for simultaneous and accurate estimation of human gait phase and terrain geometry using a small set of fabric-based wearable soft sensors, with efficient adaptation to unseen subjects and strong generalization across different subjects and terrains. Compared to rigid alternatives such as inertial measurement units, fabric-based soft sensors improve comfort but introduce nonlinearities due to hysteresis, placement error, and fabric deformation. Moreover, inter-subject and inter-terrain variability, coupled with limited calibration data in real-world deployments, further complicate accurate estimation. To address these challenges, the proposed framework integrates MAML into a deep learning architecture to learn a generalizable model initialization that captures subject- and terrain-invariant structure. This initialization enables efficient adaptation (i.e., adaptation with only a small amount of calibration data and a few fine-tuning steps) to new users, while maintaining strong generalization (i.e., high estimation accuracy across subjects and terrains). Experiments on nine participants walking at various speeds over five terrain conditions demonstrate that the proposed framework outperforms baseline approaches in estimating gait phase, locomotion mode, and incline angle, with superior accuracy, adaptation efficiency, and generalization.
format Preprint
id arxiv_https___arxiv_org_abs_2508_02930
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Model-agnostic Meta-learning for Adaptive Gait Phase and Terrain Geometry Estimation with Wearable Soft Sensors
Zhu, Zenan
Chen, Wenxi
Kao, Pei-Chun
Clark, Janelle
Behnke, Lily
Kramer-Bottiglio, Rebecca
Yanco, Holly
Gu, Yan
Robotics
This letter presents a model-agnostic meta-learning (MAML) based framework for simultaneous and accurate estimation of human gait phase and terrain geometry using a small set of fabric-based wearable soft sensors, with efficient adaptation to unseen subjects and strong generalization across different subjects and terrains. Compared to rigid alternatives such as inertial measurement units, fabric-based soft sensors improve comfort but introduce nonlinearities due to hysteresis, placement error, and fabric deformation. Moreover, inter-subject and inter-terrain variability, coupled with limited calibration data in real-world deployments, further complicate accurate estimation. To address these challenges, the proposed framework integrates MAML into a deep learning architecture to learn a generalizable model initialization that captures subject- and terrain-invariant structure. This initialization enables efficient adaptation (i.e., adaptation with only a small amount of calibration data and a few fine-tuning steps) to new users, while maintaining strong generalization (i.e., high estimation accuracy across subjects and terrains). Experiments on nine participants walking at various speeds over five terrain conditions demonstrate that the proposed framework outperforms baseline approaches in estimating gait phase, locomotion mode, and incline angle, with superior accuracy, adaptation efficiency, and generalization.
title Model-agnostic Meta-learning for Adaptive Gait Phase and Terrain Geometry Estimation with Wearable Soft Sensors
topic Robotics
url https://arxiv.org/abs/2508.02930