DocumentCode
3028411
Title
InferLoc: Calibration Free Based Location Inference for Temporal and Spatial Fine-Granularity Magnitude
Author
Zhenyu Chen ; Shuangquan Wang ; Yiqiang Chen ; Zhongtang Zhao ; Mu Lin
Author_Institution
Inst. of Comput. Technol., Beijing, China
fYear
2012
fDate
5-7 Dec. 2012
Firstpage
453
Lastpage
460
Abstract
Location is the most important information in the field of context-aware computing. Normally, one location represented as absolute physical coordinate is less understandable than semantically meaningful place like "home", "office", etc. This paper proposes a novel calibration free based algorithm called Infer Loc to infer user\´s daily significant locations using Wi-Fi signals obtained from mobile phone. Infer Loc contains three main steps: 1) Stop point detection based on trajectory segmentation through similarity calculation between neighbor sampling windows, 2) Location discovery through density based clustering and 3) Semantically significant location inference through matching clustered locations and recorded places in personal diary. Furthermore, we implement and validate Infer Loc algorithm on realistic data collected from real-world wireless environment. Experimental results show that Infer Loc can recognize visiting locations both in temporal and spatial fine-granularity magnitude under short response delay.
Keywords
inference mechanisms; mobile computing; pattern clustering; pattern matching; InferLoc; Wi-Fi signals; calibration free based location inference; clustered location matching; context-aware computing; density based clustering; location discovery; location-based service; mobile communication technology; mobile phone; neighbor sampling windows; personal diary; recorded places matching; semantically significant location inference; short response delay; similarity calculation; spatial fine-granularity magnitude; stop point detection; temporal fine-granularity magnitude; trajectory segmentation; Calibration; Clustering algorithms; Equations; Global Positioning System; IEEE 802.11 Standards; Mathematical model; Trajectory; density based clustering; location inference; significant location; stop point; trajectory segmentation;
fLanguage
English
Publisher
ieee
Conference_Titel
Computational Science and Engineering (CSE), 2012 IEEE 15th International Conference on
Conference_Location
Nicosia
Print_ISBN
978-1-4673-5165-2
Electronic_ISBN
978-0-7695-4914-9
Type
conf
DOI
10.1109/ICCSE.2012.69
Filename
6417328
Link To Document