Abstract
This paper studies binary hypothesis testing with a single sensor that communicates with two decision centers over a memoryless broadcast channel. The main focus lies on the tradeoff between the two type-II error exponents achievable at the two decision centers. In our proposed scheme, we can partially mitigate this tradeoff when the transmitter has a probability larger than 1/2 to distinguish the alternate hypotheses at the decision centers, i.e., the hypotheses under which the decision centers wish to maximize their error exponents. In the cases where these hypotheses cannot be distinguished at the transmitter (because both decision centers have the same alternative hypothesis or because the transmitter’s observations have the same marginal distribution under both hypotheses), our scheme shows an important tradeoff between the two exponents. The results in this paper thus reinforce the previous conclusions drawn for a setup where communication is over a common noiseless link. Compared to such a noiseless scenario, here, however, we observe that even when the transmitter can distinguish the two hypotheses, a small exponent tradeoff can persist, simply because the noise in the channel prevents the transmitter to perfectly describe its guess of the hypothesis to the two decision centers.
Highlights
We consider a single sensor for simplicity and because our main focus is on studying the tradeoff between the performances at the two decision centers that can arise because the single sensor has to send information over the channel that can be used by both decision centers
The other decision center keeps the transmitter’s tentative guess and ignores the rest of the communication. We extend these previous works to memoryless broadcast channels (BC)
We present general distributed hypothesis testing schemes over memoryless BCs, and we analyze the performances of these schemes with a special focus on the tradeoff in Information 2021, 12, 268 exponents they achieve for the two decision centers
Summary
Based on the sequence of channel outputs Vin and the source sequence Yin , Receiver i decides on the hypothesis H. The fundamental exponents region E depends on the joint laws PXY1 Y2 and Q XY1 Y2 only through their marginal laws PXY1 , PXY2 , Q XY1 , and Q XY2. As a consequence to the preceding Remark 1, when PX = Q X , one can restrict attention to a scenario where both receivers aim at maximizing the error exponent under hypothesis H = 1, i.e., h1 = h2 = 1.
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