Margin-Based Deep Learning Networks for Human Activity Recognition

Human activity recognition (HAR) is a popular and challenging research topic, driven by a variety of applications. More recently, with significant progress in the development of deep learning networks for classification tasks, many researchers have made use of such models to recognise human activiti...

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Veröffentlicht in:	Sensors (Basel, Switzerland) Switzerland), 2020-03, Vol.20 (7), p.1871, Article 1871
Hauptverfasser:	Lv, Tianqi, Wang, Xiaojuan, Jin, Lei, Xiao, Yabo, Song, Mei
Format:	Artikel
Sprache:	eng
Schlagworte:	Chemistry Chemistry, Analytical Deep Learning Engineering Engineering, Electrical & Electronic Human Activities human activity recognition Humans Instruments & Instrumentation Machine Learning margin mechanism Monitoring, Physiologic Neural Networks, Computer open-set classification Physical Sciences Science & Technology Technology
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creator	Lv, Tianqi Wang, Xiaojuan Jin, Lei Xiao, Yabo Song, Mei
description	Human activity recognition (HAR) is a popular and challenging research topic, driven by a variety of applications. More recently, with significant progress in the development of deep learning networks for classification tasks, many researchers have made use of such models to recognise human activities in a sensor-based manner, which have achieved good performance. However, sensor-based HAR still faces challenges; in particular, recognising similar activities that only have a different sequentiality and similarly classifying activities with large inter-personal variability. This means that some human activities have large intra-class scatter and small inter-class separation. To deal with this problem, we introduce a margin mechanism to enhance the discriminative power of deep learning networks. We modified four kinds of common neural networks with our margin mechanism to test the effectiveness of our proposed method. The experimental results demonstrate that the margin-based models outperform the unmodified models on the OPPORTUNITY, UniMiB-SHAR, and PAMAP2 datasets. We also extend our research to the problem of open-set human activity recognition and evaluate the proposed method's performance in recognising new human activities.
doi_str_mv	10.3390/s20071871
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subjects	Chemistry Chemistry, Analytical Deep Learning Engineering Engineering, Electrical & Electronic Human Activities human activity recognition Humans Instruments & Instrumentation Machine Learning margin mechanism Monitoring, Physiologic Neural Networks, Computer open-set classification Physical Sciences Science & Technology Technology
title	Margin-Based Deep Learning Networks for Human Activity Recognition
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