Detecting high indoor crowd density with Wi-Fi localization: a statistical mechanics approach

Detecting high indoor crowd density with Wi-Fi localization: a statistical mechanics approach

We address the problem of detecting highly raised crowd density in situations such as indoor dance events. We propose a new method for estimating crowd density by anonymous, non-participatory, indoor Wi-Fi localization of smart phones. Using a probabilistic model inspired by statistical mechanics, a...

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Veröffentlicht in:Journal of Big Data 2019-03, Vol.6 (1), p.1-23, Article 31
Hauptverfasser: Georgievska, Sonja, Rutten, Philip, Amoraal, Jan, Ranguelova, Elena, Bakhshi, Rena, de Vries, Ben L., Lees, Michael, Klous, Sander
Format: Artikel
Sprache:eng
Schlagworte:
Analytics
Big Data
Big data analytics
Communications Engineering
Computational Science and Engineering
Computer Science
Crowd density estimation
Crowds
Dance
Data management
Data Mining and Knowledge Discovery
Database Management
Density
Indoor Wi-Fi localization
Information Storage and Retrieval
Localization
Location-based systems
Machine learning
Mathematical Applications in Computer Science
Methodology
Methods
Networks
Optimization
Positioning devices (machinery)
Probabilistic modeling
Probabilistic models
Smart phones
Smartphones
Statistical analysis
Statistical mechanics
Volatility
Wi-Fi
Wireless telephones
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Beschreibung
Zusammenfassung:We address the problem of detecting highly raised crowd density in situations such as indoor dance events. We propose a new method for estimating crowd density by anonymous, non-participatory, indoor Wi-Fi localization of smart phones. Using a probabilistic model inspired by statistical mechanics, and relying only on big data analytics, we tackle three challenges: (1) the ambiguity of Wi-Fi based indoor positioning, which appears regardless of whether the latter is performed with machine learning or with optimization, (2) the MAC address randomization when a device is not connected, and (3) the volatility of packet interarrival times. The main result is that our estimation becomes more—rather than less—accurate when the crowd size increases. This property is crucial for detecting dangerous crowd density.
ISSN:2196-1115
2196-1115
DOI:10.1186/s40537-019-0194-3