Resource Allocation for Positive-Rate Covert Communications Using Optimization and Deep Reinforcement Learning

Abstract

We aim to achieve keyless covert communication with a positive-rate in Rayleigh block-fading channels. Specifically, the transmitter and the legitimate receiver are assumed to have either causal or non-causal knowledge of the CSI for both the legitimate and the warden channels, while the warden only knows the statistical distribution of the CSI. Two problem formulations are considered in this work: (a) Power allocation: maximizing the sum covert rate subject to a maximum power constraint, and (b) Rate allocation: minimizing the power consumption subject to a minimum covert rate constraint. Both problems are formulated based on recent information theoretical results on covert communication over state-dependent channels. When the CSI of each fading block is known non-causally, we propose a novel three-step method to solve both the power and rate allocation problems. In the case where the CSI is known causally, the power allocation problem can be formulated as MDP and be solved using a DDQN approach. Although the rate allocation problem under causal CSI does not directly conform to an MDP structure, it can be approximately solved using the DDQN trained for power allocation. Simulation results demonstrate the effectiveness of the proposed power and rate allocation methods and provide comprehensive performance comparisons across different allocation schemes.