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Recursive Distributed Detection for Composite Hypothesis Testing: Nonlinear Observation Models in Additive Gaussian Noise

Information Theory 2017-02-23 v3 math.IT Probability

Abstract

This paper studies recursive composite hypothesis testing in a network of sparsely connected agents. The network objective is to test a simple null hypothesis against a composite alternative concerning the state of the field, modeled as a vector of (continuous) unknown parameters determining the parametric family of probability measures induced on the agents' observation spaces under the hypotheses. Specifically, under the alternative hypothesis, each agent sequentially observes an independent and identically distributed time-series consisting of a (nonlinear) function of the true but unknown parameter corrupted by Gaussian noise, whereas, under the null, they obtain noise only. Two distributed recursive generalized likelihood ratio test type algorithms of the \emph{consensus+innovations} form are proposed, namely CIGLRTL\mathcal{CIGLRT-L} and CIGLRTNL\mathcal{CIGLRT-NL}, in which the agents estimate the underlying parameter and in parallel also update their test decision statistics by simultaneously processing the latest local sensed information and information obtained from neighboring agents. For CIGLRTNL\mathcal{CIGLRT-NL}, for a broad class of nonlinear observation models and under a global observability condition, algorithm parameters which ensure asymptotically decaying probabilities of errors~(probability of miss and probability of false detection) are characterized. For CIGLRTL\mathcal{CIGLRT-L}, a linear observation model is considered and upper bounds on large deviations decay exponent for the error probabilities are obtained.

Keywords

Cite

@article{arxiv.1601.04779,
  title  = {Recursive Distributed Detection for Composite Hypothesis Testing: Nonlinear Observation Models in Additive Gaussian Noise},
  author = {Anit Kumar Sahu and Soummya Kar},
  journal= {arXiv preprint arXiv:1601.04779},
  year   = {2017}
}

Comments

To appear in IEEE Transactions on Information Theory

R2 v1 2026-06-22T12:32:19.186Z