Online Travel Mode Identification Using Smartphones With Battery Saving Considerations

Personal trips in modern urban society usually involve multiple travel modes. Recognizing a traveler's transportation mode is not only critical to personal context awareness in related applications but also essential to urban traffic operations, transportation planning, and facility design. Whi...

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Bibliographic Details
Published in:IEEE transactions on intelligent transportation systems 2016-10, Vol.17 (10), p.2921-2934
Main Authors: Xing Su, Caceres, Hernan, Hanghang Tong, Qing He
Format: Article
Language:English
Subjects:
Global Positioning System
Magnetic sensors
mobile mining
online learning
Public transportation
Sensor systems
Smart phones
Traffic mode identification
vehicle classification
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Summary:Personal trips in modern urban society usually involve multiple travel modes. Recognizing a traveler's transportation mode is not only critical to personal context awareness in related applications but also essential to urban traffic operations, transportation planning, and facility design. While most current practice often leverages infrastructure-based fixed sensors or a Global Positioning System (GPS) for traffic mode recognition, the emergence of the smartphone provides an alternative promising way with its ever-growing computing, networking, and sensing power. In this paper, we propose a GPS-and-network-free method to detect a traveler's travel mode using mobile phone sensors. Our application is built on the latest Android platform with multimodality sensors. By developing a hierarchical classification method with an online learning model, we achieve almost 100% accuracy in a binary classification of wheeled/unwheeled travel modes and an average of 97.1% accuracy with all six travel modes (buses, subways, cars, bicycling, walking, and jogging). Our system (a) could adapt to each traveler's pattern by using the online learning model, and it performs significantly faster in computation than the offline model, and (b) works with a low sampling frequency for sensing so that it saves the smartphone battery.
ISSN:1524-9050
1558-0016
DOI:10.1109/TITS.2016.2530999