Distributed Adaptive Signal Estimation in Wireless Sensor Networks With Partial Prior Knowledge of the Desired Sources Steering Matrix

In the past two decades, wireless sensor networks (WSNs) and their applications have been the topic of many studies. Different multi-sensor nodes are used to collect, process and distribute data over wireless links to perform different tasks such as smart detection, target tracking, node localizatio...

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Bibliographic Details
Published in:IEEE transactions on signal and information processing over networks 2021, Vol.7, p.478-492
Main Authors: Van Rompaey, Robbe, Moonen, Marc
Format: Article
Language:English
Subjects:
Adaptive algorithms
Algorithms
Computer simulation
Convergence
Correlation
distributed estimation
Eigenvalues
Estimation
generalized eigenvalue decomposition (GEVD)
Information processing
Knowledge engineering
multichannel wiener filter (MWF)
Nodes
Noise reduction
Optimization
prior knowledge
Reference signals
Sensors
Speech enhancement
Speech processing
Steering
Target detection
Tracking
Wiener filtering
Wireless networks
Wireless sensor networks
Wireless sensor networks (WSN)
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Summary:In the past two decades, wireless sensor networks (WSNs) and their applications have been the topic of many studies. Different multi-sensor nodes are used to collect, process and distribute data over wireless links to perform different tasks such as smart detection, target tracking, node localization, etc. In this article, the problem of distributed adaptive estimation of node-specific signals for signal enhancement or noise reduction is addressed. First the centralized rank R generalized eigenvalue decomposition (GEVD) based multichannel Wiener filter (MWF) with prior knowledge for node-specific signal estimation in a WSN is introduced, where (some of) the nodes have partial prior knowledge of the desired sources steering matrix. A distributed adaptive estimation algorithm for a fully-connected WSN is then proposed demonstrating that this MWF can be obtained by letting the nodes work on compressed (i.e. reduced-dimensional) sensor signals compared to the centralized algorithm. The distributed algorithm can be used in applications such as speech enhancement in a wireless acoustic sensor network (WASN), where (some of) the nodes have prior knowledge on the location of the desired speech sources and on their local microphone array geometry or have access to clean noise reference signals. Foundations for a proof of convergence using a Lagrangian framework, are given, since convergence is observed in batch-mode simulations. Finally, numerical simulation results are provided for a speech enhancement scenario.
ISSN:2373-776X
2373-776X
2373-7778
DOI:10.1109/TSIPN.2021.3098941