Distributed Hypothesis Testing with Collaborative Detection

2018 56th Annual Allerton Conference on Communication, Control, and Computing (Allerton) Pub Date : 2018-10-01 DOI:10.1109/ALLERTON.2018.8635828

Pierre Escamilla, A. Zaidi, M. Wigger

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引用次数: 8

Abstract

A detection system with a single sensor and two detectors is considered, where each of the terminals observes a memoryless source sequence, the sensor sends a message to both detectors and the first detector sends a message to the second detector. Communication of these messages is assumed to be error-free but rate-limited. The joint probability mass function (pmf) of the source sequences observed at the three terminals depends on an M-ary hypothesis $( \mathrm{M}\ge 2)$, and the goal of the communication is that each detector can guess the underlying hypothesis. Detector $k, k = 1,2$, aims to maximize the error exponent under hypothesis ${i}_{k}, i_{k}\, \in\{ 1,\ldots ,\mathrm{M}\}$, while ensuring a small probability of error under all other hypotheses. We study this problem in the case in which the detectors aim to maximize their error exponents under the same hypothesis (i.e., $i_{1}\,= \quad i_{2})$ and in the case in which they aim to maximize their error exponents under distinct hypotheses (i.e., $i_{1}\, 6 = \quad i_{2})$. For the setting in which $i_{1}\,= \quad i_{2}$, we present an achievable exponents region for the case of positive communication rates, and show that it is optimal for a specific case of testing against independence. We also characterize the optimal exponents region in the case of zero communication rates. For the setting in which $i_{1}\, 6 = \quad i_{2}$, we characterize the optimal exponents region in the case of zero communication rates.

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协同检测的分布式假设检验

考虑一种具有单传感器和两个探测器的检测系统，其中每个终端观察无记忆源序列，传感器向两个探测器发送消息，第一个探测器向第二个探测器发送消息。假设这些消息的通信是无错误的，但速率有限。在三个终端观测到的源序列的联合概率质量函数(pmf)依赖于一个M-ary假设$(\mathrm{M}\ge 2)$，通信的目标是每个探测器都能猜测到潜在的假设。检测器$k, k = 1,2$的目标是在假设${i}_{k}， i_{k}\， \in\{1，\ldots，\mathrm{M}\}$下使误差指数最大化，同时保证在所有其他假设下的误差概率很小。我们研究了两种情况，一种是检测器的目标是在相同假设下(即$i_{1}\，= \quad i_{2})$最大化它们的误差指数，另一种是检测器的目标是在不同假设下(即$i_{1}\， 6 = \quad i_{2})$最大化它们的误差指数。对于$i_{1}\，= \quad i_{2}$的设置，我们给出了正通信率情况下可实现的指数区域，并证明了它对于独立性测试的特定情况是最优的。我们还描述了零通信速率情况下的最优指数区域。对于$i_{1}\， 6 = \quad i_{2}$的设置，我们刻画了零通信速率情况下的最优指数区域。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2018 56th Annual Allerton Conference on Communication, Control, and Computing (Allerton)

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