Finite-SNR regime analysis of the Gaussian wiretap multiple-access channel

P. Babaheidarian, Somayeh Salimi, Panos Papadimitratos
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引用次数: 11

Abstract

In this work, we consider a K-user Gaussian wiretap multiple-access channel (GW-MAC) in which each transmitter has an independent confidential message for the receiver. There is also an external eavesdropper who intercepts the communications. The goal is to transmit the messages reliably while keeping them confidential from the eavesdropper. To accomplish this goal, two different approaches have been proposed in prior works, namely, i.i.d. Gaussian random coding and real alignment. However, the former approach fails at moderate and high SNR regimes as its achievable result does not grow with SNR. On the other hand, while the latter approach gives a promising result at the infinite SNR regime, its extension to the finite-SNR regime is a challenging task. To fill the gap between the performance of the existing approaches, in this work, we establish a new scheme in which, at the receiver's side, it utilizes an extension of the compute-and-forward decoding strategy and at the transmitters' side it exploits lattice alignment, cooperative jamming, and i.i.d. random codes. For the proposed scheme, we derive a new achievable bound on sum secure rate which scales with log(SNR) and hence it outperforms the i.i.d. Gaussian codes in moderate and high SNR regimes. We evaluate the performance of our scheme, both theoretically and numerically. Furthermore, we show that our sum secure rate achieves the optimal sum secure degrees of freedom in the infinite-SNR regime.
高斯窃听多址信道的有限信噪比谱分析
在这项工作中,我们考虑了一个k用户高斯窃听多址信道(GW-MAC),其中每个发送者都有一个独立的机密消息给接收者。还有一个外部窃听者拦截通信。目标是可靠地传输消息,同时对窃听者保密。为了实现这一目标,在之前的工作中提出了两种不同的方法,即高斯随机编码和实对齐。然而,前一种方法在中等和高信噪比条件下失败,因为其可实现的结果不随信噪比增长。另一方面,虽然后一种方法在无限信噪比下给出了很好的结果,但将其推广到有限信噪比下是一项具有挑战性的任务。为了填补现有方法之间的性能差距,在这项工作中,我们建立了一个新的方案,其中,在接收端,它利用了计算机和前向解码策略的扩展,在发送端,它利用了晶格对齐,协同干扰和i.i.d.随机码。对于所提出的方案,我们推导了一个新的可实现的和安全率的边界,该边界随对数(SNR)的扩展而扩展,因此它在中高信噪比下优于i.i.d高斯码。我们从理论上和数值上评估了我们的方案的性能。进一步,我们证明了我们的和安全率达到了无限信噪比下的最优和安全自由度。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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