Multi-User Covert Communication in Spatially Heterogeneous Wireless Networks

TL;DR

This paper models spatially heterogeneous multi-user covert communication systems, deriving optimal strategies and demonstrating that accounting for user location improves covert performance over homogeneous assumptions.

Contribution

It introduces a geometric position-aware model and an optimal power control scheme for covert communication in heterogeneous wireless networks.

Findings

Optimal on-off power control scheme for heterogeneous environments.

Closed-form expressions for detection error probability and cooperative users.

Spatial heterogeneity enhances covert communication performance.

Abstract

This paper investigates an uplink multi-user covert communication system with spatially distributed users. Unlike prior works that approximate channel statistics using averaged parameters and homogeneous assumptions, this study explicitly models each user's geometric position and corresponding user-to-Willie and user-to-Bob channel variances. This approach enables an accurate characterization of spatially heterogeneous covert environments. We mathematically prove that a generalized on-off power control scheme, which jointly accounts for both Bob's and Willie's channels, constitutes the optimal transmission strategy in heterogeneous user configurations. Leveraging the optimal strategy, we derive closed-form expressions for the minimum detection error probability and the minimum number of cooperative users required to satisfy a covert constraint. With the closed-form expressions, comprehensive theoretical analyses are conducted, which are validated by Monte-Carlo simulations. One important insight obtained from the analysis is that user spatial heterogeneity can enhance covert communication performance. Building on these findings, a piecewise search algorithm is proposed to achieve exact optimality with significantly reduced computational complexity. We demonstrate that optimization considering user's spatial heterogeneity achieves substantially improved covert communication performance than that based on the assumption of spatial homogeneity.