@inproceedings{3ccb302fcf7c44609f2acbe0bd2da180,
title = "On the Performance of Decentralized Detection Under Transmission Constraints",
abstract = " We consider the problem of distributed detection in a wireless network consisting of a large number of sensors having either ideal or non-ideal communication links to their respective fusion or relay node. The detection performance is characterized under a Neyman-Pearson framework using a parallel configuration and a single-rooted tree with bounded height, where only the leaves are sensors. We show that with conditionally independent observations across sensors, the Type II error exponent for a single-rooted tree of uniform height two can be equivalent to that of a parallel configuration under certain conditions. These conditions include the ability to group sensors into sub-classes, where the observations within a class are conditionally independent and identically distributed, and with binary decision throughout. We then show that a single rooted tree can achieve improved detection performance versus the parallel configuration with the same number of nodes under multipath fading communication links and a constrained transmit power budget in the non-asymptotic regime.",
keywords = "Distributed Detection, KullbackLeibler Divergence, Multipath Fading, Power Savings, Sensor Classes, Uniform Relay Tree",
author = "Uri Rogers and Hao Chen",
note = "Publisher Copyright: {\textcopyright} 2014 IEEE.; 2014 National Wireless Research Collaboration Symposium, NWRCS 2014 ; Conference date: 15-05-2014 Through 16-05-2014",
year = "2014",
doi = "10.1109/NWRCS.2014.29",
language = "American English",
series = "Proceedings of the National Wireless Research Collaboration Symposium",
publisher = "Institute of Electrical and Electronics Engineers Inc.",
pages = "133--138",
booktitle = "Proceedings of the 2014 National Wireless Research Collaboration Symposium",
}