Bibliographic Information: Khaledian, F., Asvadi, R., Dupraz, E., & Matsumoto, T. (2024). Covering Codes as Near-Optimal Quantizers for Distributed Testing Against Independence. arXiv preprint arXiv:2410.15839.
Research Objective: This paper investigates the optimal design of local quantizers for distributed hypothesis testing against independence, focusing on binary symmetric sources. The authors aim to characterize the optimal quantizer among binary linear codes, particularly for short code-length regimes, and derive error exponents for large code-length regimes.
Methodology: The authors utilize analytical expressions for Type-I and Type-II error probabilities for Minimum Distance (MD) quantizers implemented with binary linear codes. They propose an alternating optimization (AO) algorithm to identify the optimal coset leader spectrum of linear block codes and the decision threshold under the Neyman-Pearson (NP) criterion. Additionally, they derive lower and upper bounds on error probabilities to analyze error exponents for large code lengths.
Key Findings: The proposed AO algorithm effectively identifies optimal or near-optimal coset leader spectrums for minimizing Type-II error probability while satisfying a constraint on Type-I error probability. Numerical results demonstrate that binary linear codes with optimal covering radius perform near-optimally for the independence test in distributed hypothesis testing. The derived error exponents provide insights into the performance of these codes in large code-length regimes.
Main Conclusions: The research concludes that binary linear codes, especially those with optimal covering radius, can serve as near-optimal quantizers for distributed hypothesis testing against independence. The study highlights the importance of the covering radius as a key parameter influencing the performance of these codes in such scenarios.
Significance: This work contributes to the practical coding aspects of distributed hypothesis testing, a field with significant implications for collaborative decision-making in sensor networks and other distributed systems. The findings provide valuable insights for designing efficient and reliable distributed detection schemes.
Limitations and Future Research: The research primarily focuses on binary symmetric sources. Exploring the applicability of the proposed methods to other source distributions and investigating the impact of noisy channels on the performance of the quantizers are potential avenues for future research.
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