Abstract
Wearable sensors-based human activity recognition introduces many useful applications and services in health care, rehabilitation training, elderly monitoring and many other areas of human interaction. Existing works in this field mainly focus on recognizing activities by using traditional features extracted from Fourier transform (FT) or wavelet transform (WT). However, these signal processing approaches are suitable for a linear signal but not for a nonlinear signal. In this paper, we investigate the characteristics of the Hilbert-Huang transform (HHT) for dealing with activity data with properties such as nonlinearity and non-stationarity. A multi-features extraction method based on HHT is then proposed to improve the effect of activity recognition. The extracted multi-features include instantaneous amplitude (IA) and instantaneous frequency (IF) by means of empirical mode decomposition (EMD), as well as instantaneous energy density (IE) and marginal spectrum (MS) derived from Hilbert spectral analysis. Experimental studies are performed to verify the proposed approach by using the PAMAP2 dataset from the University of California, Irvine for wearable sensors-based activity recognition. Moreover, the effect of combining multi-features vs. a single-feature are investigated and discussed in the scenario of a dependent subject. The experimental results show that multi-features combination can further improve the performance measures. Finally, we test the effect of multi-features combination in the scenario of an independent subject. Our experimental results show that we achieve four performance indexes: recall, precision, F-measure, and accuracy to 0.9337, 0.9417, 0.9353, and 0.9377 respectively, which are all better than the achievements of related works.
Highlights
Services provided by computing devices have shifted from proprietary computing services to flexible services focusing on human need
This section introduces how to use the features of Hilbert-Huang transform (HHT) for activity recognition
In order to compare our results with [54], this paper uses same performance measures: recall, precision, F-measure and accuracy, which are commonly used in the field of classification
Summary
Services provided by computing devices have shifted from proprietary computing services to flexible services focusing on human need. Computer systems are closely linked to human users by natural interaction methods. How to recognize human activities is an important part of supporting technology for these computer systems. Two of the major identification methods are based on vision sensors and wearable sensors. Identification methods, which are based on computer vision, use images taken with cameras, and these images are intuitive and understandable. Since the human body is particular, and activity is ambiguous, diversiform, and different in space and time, it is difficult to get a higher recognition rate with computer vision-based methods. The use of cameras is limited by factors such as light conditions and install locations. Activity recognition based on wearable sensors has become more and more popular
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