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Auteurs principaux: Pugazhenthi, Veeramani, Chu, Wei-Hsiang, Lu, Junwei, Miyahira, Jadyn N., Eslamimehr, Mahdi, Satam, Pratik, Yasaei, Rozhin, Salehi, Soheil
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2512.00008
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author Pugazhenthi, Veeramani
Chu, Wei-Hsiang
Lu, Junwei
Miyahira, Jadyn N.
Eslamimehr, Mahdi
Satam, Pratik
Yasaei, Rozhin
Salehi, Soheil
author_facet Pugazhenthi, Veeramani
Chu, Wei-Hsiang
Lu, Junwei
Miyahira, Jadyn N.
Eslamimehr, Mahdi
Satam, Pratik
Yasaei, Rozhin
Salehi, Soheil
contents The use of tiny devices capable of low-latency gesture recognition is gaining momentum in everyday human-computer interaction and especially in medical monitoring fields. Embedded solutions such as fall detection, rehabilitation tracking, and patient supervision require fast and efficient tracking of movements while avoiding unwanted false alarms. This study presents an efficient solution on how to build very efficient motion-based models only using triaxial accelerometer sensors. We explore the capability of the AutoML pipelines to extract the most important features from the data segments. This approach also involves training multiple lightweight machine learning algorithms using the extracted features. We use WeBe Band, a multi-sensor wearable device that is equipped with a powerful enough MCU to effectively perform gesture recognition entirely on the device. Of the models explored, we found that the neural network provided the best balance between accuracy, latency, and memory use. Our results also demonstrate that reliable real-time gesture recognition can be achieved in WeBe Band, with great potential for real-time medical monitoring solutions that require a secure and fast response time.
format Preprint
id arxiv_https___arxiv_org_abs_2512_00008
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle MOTION: ML-Assisted On-Device Low-Latency Motion Recognition
Pugazhenthi, Veeramani
Chu, Wei-Hsiang
Lu, Junwei
Miyahira, Jadyn N.
Eslamimehr, Mahdi
Satam, Pratik
Yasaei, Rozhin
Salehi, Soheil
Computer Vision and Pattern Recognition
Artificial Intelligence
Human-Computer Interaction
The use of tiny devices capable of low-latency gesture recognition is gaining momentum in everyday human-computer interaction and especially in medical monitoring fields. Embedded solutions such as fall detection, rehabilitation tracking, and patient supervision require fast and efficient tracking of movements while avoiding unwanted false alarms. This study presents an efficient solution on how to build very efficient motion-based models only using triaxial accelerometer sensors. We explore the capability of the AutoML pipelines to extract the most important features from the data segments. This approach also involves training multiple lightweight machine learning algorithms using the extracted features. We use WeBe Band, a multi-sensor wearable device that is equipped with a powerful enough MCU to effectively perform gesture recognition entirely on the device. Of the models explored, we found that the neural network provided the best balance between accuracy, latency, and memory use. Our results also demonstrate that reliable real-time gesture recognition can be achieved in WeBe Band, with great potential for real-time medical monitoring solutions that require a secure and fast response time.
title MOTION: ML-Assisted On-Device Low-Latency Motion Recognition
topic Computer Vision and Pattern Recognition
Artificial Intelligence
Human-Computer Interaction
url https://arxiv.org/abs/2512.00008