Accurate GSM Indoor Localization

Otsason, Veljo; Varshavsky, Alex; LaMarca, Anthony; Lara, Eyal de

doi:10.1007/11551201_9

Cited by 327 publications

(211 citation statements)

References 17 publications

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“…Research using mobile phone data has mostly focused on locationdriven data analysis, more specifically, using Global Positioning System (GPS) data to predict transportation mode [Patterson et al 2003,Reddy et al 2008, to predict user destinations [Krumm and Horvitz 2006] or paths [Akoush and Sameh 2007], and to predict daily step count [Sohn et al 2006]. Other location-driven tasks have made use of Global System for Mobile Communications (GSM) data for indoor localization [Otsason et al 2005] or WiFi for large-scale localization [Letchner et al 2005]. The BeaconPrint algorithm [Hightower et al 2005] uses both WiFi and GSM to learn the places a user goes and detect if the user returns to these places.…”

Section: Related Workmentioning

confidence: 99%

Discovering routines from large-scale human locations using probabilistic topic models

Farrahi

Gática-Pérez

2011

ACM Trans. Intell. Syst. Technol.

193

109

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In this work we discover the daily location-driven routines which are contained in a massive reallife human dataset collected by mobile phones. Our goal is the discovery and analysis of human routines which characterize both individual and group behaviors in terms of location patterns. We develop an unsupervised methodology based on two differing probabilistic topic models and apply them to the daily life of 97 mobile phone users over a 16 month period to achieve these goals. Topic models are probabilistic generative models for documents that identify the latent structure that underlies a set of words. Routines dominating the entire group's activities, identified with a methodology based on the Latent Dirichlet Allocation topic model, include "going to work late", "going home early", "working non-stop" and "having no reception (phone off)" at different times over varying time-intervals. We also detect routines which are characteristic of users, with a methodology based on the Author-Topic model. With the routines discovered, and the two methods of characterizing days and users, we can then perform various tasks. We use the routines discovered to determine behavioral patterns of users and groups of users. For example, we can find individuals that display specific daily routines, such as "going to work early" or "turning off the mobile (or having no reception) in the evenings". We are also able to characterize daily patterns by determining the topic structure of days in addition to determining whether certain routines occur dominantly on weekends or weekdays. Furthermore, the routines discovered can be used to rank users or find subgroups of users who display certain routines. We can also characterize users based on their entropy. We compare our method to one based on clustering using K-means. Finally, we analyze an individual's routines over time to determine regions with high variations, which may correspond to specific events.

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Section: Related Workmentioning

confidence: 99%

Discovering routines from large-scale human locations using probabilistic topic models

Farrahi

Gática-Pérez

2011

ACM Trans. Intell. Syst. Technol.

193

109

View full text Add to dashboard Cite

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“…The RADAR system [4] was a building wide tracking system using wireless LAN. The work in [13] relies on the GSM cell towers id and signal strength for indoor localization. The E911 emergency tracking system locates people who call 911 by doing sophisticated radio signaling and computing the time of arrival,and time difference of arrival from cellphone to perform accurate triangulation.…”

Section: Related Workmentioning

confidence: 99%

“…However, when we enter a building the reception of GPS signals become weak or is lost causing the inability to determine additional location information within the building. Existing solutions for indoor localization include techniques that use WiFi [4], RFID, Bluetooth [2], ultrasound [16], infrared [19] and GSM [17] [13] etc. Many of these solutions rely on external infrastructure or a network of nodes to perform localization.…”

Section: Introductionmentioning

confidence: 99%

Coarse In-Building Localization with Smartphones

Parnandi

Le²,

Vaghela³

et al. 2010

Lecture Notes of the Institute for Computer Sciences, Social Informatics and Telecommunications Engineering

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Abstract. Geographic location of a person is important contextual information that can be used in a variety of scenarios like disaster relief, directional assistance, context-based advertisements, etc. GPS provides accurate localization outdoors but is not useful inside buildings. We propose an coarse indoor localization approach that exploits the ubiquity of smart phones with embedded sensors. GPS is used to find the building in which the user is present. The Accelerometers are used to recognize the user's dynamic activities (going up or down stairs or an elevator) to determine his/her location within the building. We demonstrate the ability to estimate the floor-level of a user. We compare two techniques for activity classification, one is naive Bayes classifier and the other is based on dynamic time warping. The design and implementation of a localization application on the HTC G1 platform running Google Android is also presented.

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“…Similar methods were applied to GSM signals by Otsason et al [3]. Unlike RADAR, later systems employed probabilistic models instead of deterministic ones.…”

Section: Related Workmentioning

confidence: 99%

GammaSense: Infrastructureless Positioning Using Background Radioactivity

Bucur

Kjærgaard

2008

Lecture Notes in Computer Science

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Abstract. We introduce the harvesting of natural background radioactivity for positioning. Using a standard Geiger-Müller counter as sensor, we fingerprint the natural levels of gamma radiation with the aim of then roughly pinpointing the position of a client in terms of interfloor, intrafloor, and indoor-versus-outdoor locations. We find that the performance of a machine-learning algorithm in detecting position varies with the building, and is highest for interfloor detection in the case of an old domestic house, while it is highest for intrafloor detection if the floor spans building segments made from different construction materials. Altogether, the technique has lower performance than infrastructure-based localization techniques.

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Accurate GSM Indoor Localization

Cited by 327 publications

References 17 publications

Discovering routines from large-scale human locations using probabilistic topic models

Discovering routines from large-scale human locations using probabilistic topic models

Coarse In-Building Localization with Smartphones

GammaSense: Infrastructureless Positioning Using Background Radioactivity

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