Distributed Detection over Noisy Networks: Large Deviations Analysis

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, all sensors can achieve exponential decay e-k Cdis 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 αk, by which sensors weigh their neighbors' messages. The optimal design of αk balances the opposing effects of communication noise and information flow from neighbors: larger, slowly decaying αk improves information flow but injects more communication noise. Further, we quantify the best achievable Cdis 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.