DocumentCode
818193
Title
Distributed Adaptive Quantization for Wireless Sensor Networks: From Delta Modulation to Maximum Likelihood
Author
Fang, Jun ; Li, Hongbin
Author_Institution
Dept. of Electr. & Comput. Eng., Stevens Inst. of Technol., Hoboken, NJ
Volume
56
Issue
10
fYear
2008
Firstpage
5246
Lastpage
5257
Abstract
We consider distributed parameter estimation using quantized observations in wireless sensor networks (WSNs) where, due to bandwidth constraint, each sensor quantizes its local observation into one bit of information. A conventional fixed quantization (FQ) approach, which employs a fixed threshold for all sensors, incurs an estimation error growing exponentially with the difference between the threshold and the unknown parameter to be estimated. To address this difficulty, we propose a distributed adaptive quantization (AQ) approach, which, with sensors sequentially broadcasting their quantized data, allows each sensor to adaptively adjust its quantization threshold. Three AQ schemes are presented: (1) AQ-FS that involves distributed delta modulation (DM) with a fixed stepsize, (2) AQ-VS that employs DM with a variable stepsize, and (3) AQ-ML that adjusts the threshold through a maximum likelihood (ML) estimation process. The ML estimators associated with the three AQ schemes are developed and their corresponding Cramer-Rao bounds (CRBs) are analyzed. We show that our 1-bit AQ approach is asymptotically optimum, yielding an asymptotic CRB that is only pi/2 times that of the clairvoyant sample-mean estimator using unquantized observations.
Keywords
delta modulation; maximum likelihood estimation; quantisation (signal); wireless sensor networks; Cramer-Rao bounds; bandwidth constraint; delta modulation; distributed adaptive quantization; distributed parameter estimation; maximum likelihood estimaton; wireless sensor networks; Adaptive quantization (AQ); distributed estimation; wireless sensor networks (WSNs);
fLanguage
English
Journal_Title
Signal Processing, IEEE Transactions on
Publisher
ieee
ISSN
1053-587X
Type
jour
DOI
10.1109/TSP.2008.928956
Filename
4579689
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