Automated Mobility Context Detection with Inertial Signals
- URL: http://arxiv.org/abs/2205.08409v1
- Date: Mon, 16 May 2022 09:34:43 GMT
- Title: Automated Mobility Context Detection with Inertial Signals
- Authors: Antonio Bevilacqua, Lisa Alcock, Brian Caulfield, Eran Gazit, Clint
Hansen, Neil Ireson, Georgiana Ifrim
- Abstract summary: The primary goal of this paper is the investigation of context detection for remote monitoring of daily motor functions.
We aim to understand whether inertial signals sampled with wearable accelerometers, provide reliable information to classify gait-related activities as either indoor or outdoor.
- Score: 7.71058263701836
- License: http://creativecommons.org/licenses/by-nc-sa/4.0/
- Abstract: Remote monitoring of motor functions is a powerful approach for health
assessment, especially among the elderly population or among subjects affected
by pathologies that negatively impact their walking capabilities. This is
further supported by the continuous development of wearable sensor devices,
which are getting progressively smaller, cheaper, and more energy efficient.
The external environment and mobility context have an impact on walking
performance, hence one of the biggest challenges when remotely analysing gait
episodes is the ability to detect the context within which those episodes
occurred. The primary goal of this paper is the investigation of context
detection for remote monitoring of daily motor functions. We aim to understand
whether inertial signals sampled with wearable accelerometers, provide reliable
information to classify gait-related activities as either indoor or outdoor. We
explore two different approaches to this task: (1) using gait descriptors and
features extracted from the input inertial signals sampled during walking
episodes, together with classic machine learning algorithms, and (2) treating
the input inertial signals as time series data and leveraging end-to-end
state-of-the-art time series classifiers. We directly compare the two
approaches through a set of experiments based on data collected from 9 healthy
individuals. Our results indicate that the indoor/outdoor context can be
successfully derived from inertial data streams. We also observe that time
series classification models achieve better accuracy than any other
feature-based models, while preserving efficiency and ease of use.
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