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Main Authors: Cartocci, Nicholas, Gkikakis, Antonios E., Kurvina, Natalia, Takele, Natnael, Pera, Fabio, Settino, Maria Teresa, Caldwell, Darwin G., Ortiz, Jesús
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2505.20917
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author Cartocci, Nicholas
Gkikakis, Antonios E.
Kurvina, Natalia
Takele, Natnael
Pera, Fabio
Settino, Maria Teresa
Caldwell, Darwin G.
Ortiz, Jesús
author_facet Cartocci, Nicholas
Gkikakis, Antonios E.
Kurvina, Natalia
Takele, Natnael
Pera, Fabio
Settino, Maria Teresa
Caldwell, Darwin G.
Ortiz, Jesús
contents A key aspect of developing fall prevention systems is the early prediction of a fall before it occurs. This paper presents a statistical overview of results obtained by analyzing 22 activities of daily living to recognize physiological patterns and estimate the risk of an imminent fall. The results demonstrate distinctive patterns between high-intensity and low-intensity activity using EMG, ECG, and respiration sensors, also indicating the presence of a proportional trend between movement velocity and muscle activity. These outcomes highlight the potential benefits of using these sensors in the future to direct the development of an activity recognition and risk prediction framework for physiological phenomena that can cause fall injuries.
format Preprint
id arxiv_https___arxiv_org_abs_2505_20917
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Recognition of Physiological Patterns during Activities of Daily Living Using Wearable Biosignal Sensors
Cartocci, Nicholas
Gkikakis, Antonios E.
Kurvina, Natalia
Takele, Natnael
Pera, Fabio
Settino, Maria Teresa
Caldwell, Darwin G.
Ortiz, Jesús
Signal Processing
A key aspect of developing fall prevention systems is the early prediction of a fall before it occurs. This paper presents a statistical overview of results obtained by analyzing 22 activities of daily living to recognize physiological patterns and estimate the risk of an imminent fall. The results demonstrate distinctive patterns between high-intensity and low-intensity activity using EMG, ECG, and respiration sensors, also indicating the presence of a proportional trend between movement velocity and muscle activity. These outcomes highlight the potential benefits of using these sensors in the future to direct the development of an activity recognition and risk prediction framework for physiological phenomena that can cause fall injuries.
title Recognition of Physiological Patterns during Activities of Daily Living Using Wearable Biosignal Sensors
topic Signal Processing
url https://arxiv.org/abs/2505.20917