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A Cognitive Radio Tracking System for Indoor Environments

Advances in wireless communication have enabled mobility of personal computing services equipped with sensing and computing capabilities. This has motivated the development of location-based services (LBS) that are implemented on top of existing communication infrastructures to cater to
changing user contexts. To enable and support the delivery of LBS, accurate, reliable, and realtime user location information is needed. This thesis introduces a cognitive dynamic system for tracking the position of mobile users using received signal strength (RSS) in Wireless Local Area Networks (WLAN).

The main challenge in WLAN positioning is the unpredictable nature of the RSS-position
relationship. Existing system rely on a set of training samples collected at a set of anchor points
with known positions in the environment to characterize this relationship. The first contribution
of this thesis is the use of nonparametric kernel density estimation for minimum mean square error
positioning using the RSS training data. This formulation enables the rigorous study of state-space
filtering in the context of WLAN positioning. The outcome is the Nonparametric Information (NI)
filter, a novel recursive position estimator that incorporates both RSS measurements and a dynamic
model of pedestrian motion during estimation. In contrast to traditional Kalman filtering
approaches, the NI filter does not require the explicit knowledge of RSS-position relationship and
is therefore well-suited for the WLAN positioning problem.

The use of the dynamic motion model by the NI filter leads to the design of a cognitive dynamic
tracking system. This design harnesses the benefits of feedback and position predictions from the
filter to guide the selection of anchor points and radio sensors used during estimation.
Experimental results using real measurement from an office environment demonstrate the
effectiveness of proactive determination of sensing and estimation parameters in mitigating
difficulties that arise due to the unpredictable nature of the indoor radio environment. In
particular, the results indicate that the proposed cognitive design achieves an improvement of
3.19m (56\%) in positioning error relative to memoryless positioning alone.

Identiferoai:union.ndltd.org:TORONTO/oai:tspace.library.utoronto.ca:1807/17260
Date26 February 2009
CreatorsKushki, Azadeh
ContributorsPlataniotis, Konstantinos N., Venetsanopoulos, Anastasios N.
Source SetsUniversity of Toronto
Languageen_ca
Detected LanguageEnglish
TypeThesis
Format1275235 bytes, application/pdf

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