Total Variation Distance Based Performance Analysis of Covert Communication over AWGN Channels in Non-asymptotic Regime

TL;DR

This paper analyzes covert communication over AWGN channels in finite block length regimes using TVD, providing bounds, asymptotics, and practical power estimation methods to enhance understanding of covert communication performance.

Contribution

It introduces new TVD-based bounds and asymptotic analysis for covert communication in finite regimes, along with practical approximation formulas for power estimation.

Findings

Derived bounds on covert throughput under TVD constraints

Presented analytic solutions and approximations for TVD based on SNR

Enhanced power estimation accuracy for covert communication

Abstract

This paper investigates covert communication over an additive white Gaussian noise (AWGN) channel in finite block length regime on the assumption of Gaussian codebooks. We first review some achievability and converse bounds on the throughput under maximal power constraint. From these bounds and the analysis of TVD at the adversary, the first and second asymptotics of covert communication are investigated by the help of some divergences inequalities. Furthermore, the analytic solution of TVD, and approximation expansions which can be easily evaluated with given snr (signal noise ratio) are presented. In this way, the proper power level for covert communication can be approximated with given covert constraint of TVD, which leads to more accurate estimation of the power compared with preceding bounds. Further elaboration on the effect of such asymptotic characteristics on the primary channels's throughput in finite block regime is also provided. The results will be very helpful for understanding the behavior of the total variation distance and practical covert communication.