Feature selection for wearable smartphone-based human activity recognition with able bodied, elderly, and stroke patients.

Nicole A Capela,Edward D Lemaire,Natalie Baddour,Christian Lovis

doi:10.1371/journal.pone.0124414

Nicole A Capela, Edward D Lemaire + Show 2 more

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https://doi.org/10.1371/journal.pone.0124414

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Journal: PloS one	Publication Date: Apr 17, 2015
Citations: 174	License type: CC BY 4.0

Affiliation: University of Ottawa, Ottawa Hospital

Abstract

Human activity recognition (HAR), using wearable sensors, is a growing area with the potential to provide valuable information on patient mobility to rehabilitation specialists. Smartphones with accelerometer and gyroscope sensors are a convenient, minimally invasive, and low cost approach for mobility monitoring. HAR systems typically pre-process raw signals, segment the signals, and then extract features to be used in a classifier. Feature selection is a crucial step in the process to reduce potentially large data dimensionality and provide viable parameters to enable activity classification. Most HAR systems are customized to an individual research group, including a unique data set, classes, algorithms, and signal features. These data sets are obtained predominantly from able-bodied participants. In this paper, smartphone accelerometer and gyroscope sensor data were collected from populations that can benefit from human activity recognition: able-bodied, elderly, and stroke patients. Data from a consecutive sequence of 41 mobility tasks (18 different tasks) were collected for a total of 44 participants. Seventy-six signal features were calculated and subsets of these features were selected using three filter-based, classifier-independent, feature selection methods (Relief-F, Correlation-based Feature Selection, Fast Correlation Based Filter). The feature subsets were then evaluated using three generic classifiers (Naïve Bayes, Support Vector Machine, j48 Decision Tree). Common features were identified for all three populations, although the stroke population subset had some differences from both able-bodied and elderly sets. Evaluation with the three classifiers showed that the feature subsets produced similar or better accuracies than classification with the entire feature set. Therefore, since these feature subsets are classifier-independent, they should be useful for developing and improving HAR systems across and within populations.

Highlights

Human activity monitoring and classification from wearable sensors can provide valuable information on patient mobility outside a hospital setting
Many human activity recognition (HAR) systems have been developed for smartphone use [1], some using internal sensors and others interfacing with external biological sensors [2]
For the able-bodied group (Table 4), features selected by Correlation-based Feature Selection (CFS) and Fast Correlation Based Filter (FCBF) methods were similar

Summary

Introduction

Human activity monitoring and classification from wearable sensors can provide valuable information on patient mobility outside a hospital setting. While research in this area has received substantial attention in recent years, most research has involved able-bodied populations and proprietary hardware. An activity monitoring approach that works with ubiquitous technologies and is applicable across clinical populations would greatly benefit evidence-based decision making for people with mobility deficits. Smartphones provide an ideal wearable computing environment that is convenient, easy to use, and rich with sensors, computing power, and storage. Most commercial smartphones include accelerometers and gyroscopes, making them an ideal candidate for activity monitoring in real-world or rehabilitation settings

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