English

Distributed Detection over Noisy Networks: Large Deviations Analysis

Information Theory 2015-05-30 v1 math.IT

Abstract

We study the large deviations performance of consensus+innovations distributed detection over noisy networks, where sensors at a time step k cooperate with immediate neighbors (consensus) and assimilate their new observations (innovation.) We show that, even under noisy communication, \emph{all sensors} can achieve exponential decay e^{-k C_{\mathrm{dis}}} of the detection error probability, even when certain (or most) sensors cannot detect the event of interest in isolation. We achieve this by designing a single time scale stochastic approximation type distributed detector with the optimal weight sequence {\alpha_k}, by which sensors weigh their neighbors' messages. The optimal design of {\alpha_k} balances the opposing effects of communication noise and information flow from neighbors: larger, slowly decaying \alpha_k improves information flow but injects more communication noise. Further, we quantify the best achievable C_{\mathrm{dis}} as a function of the sensing signal and noise, communication noise, and network connectivity. Finally, we find a threshold on the communication noise power below which a sensor that can detect the event in isolation still improves its detection by cooperation through noisy links.

Keywords

Cite

@article{arxiv.1108.1410,
  title  = {Distributed Detection over Noisy Networks: Large Deviations Analysis},
  author = {Dusan Jakovetic and Jose M. F. Moura and Joao Xavier},
  journal= {arXiv preprint arXiv:1108.1410},
  year   = {2015}
}

Comments

30 pages, journal, submitted August 2nd, 2011

R2 v1 2026-06-21T18:47:11.425Z