Analysis of Multi-Hop Outdoor 60 GHz Wireless Networks with Full-Duplex Buffered Relays

TL;DR

This paper proposes a multi-hop outdoor 60 GHz wireless network with full-duplex relays, analyzing its performance and the impact of self-interference, and introduces an optimal power allocation scheme to improve network reliability.

Contribution

It introduces a novel performance analysis framework for multi-hop 60 GHz outdoor networks with self-interference, including probabilistic bounds and relay density effects.

Findings

Increasing relay density can degrade performance if self-interference isn't minimized.

Optimal power allocation can mitigate self-interference effects.

Probabilistic bounds on delay and backlog are derived for the network.

Abstract

The abundance of unlicensed spectrum in the 60 GHz band makes it an attractive alternative for future wireless communication systems. Such systems are expected to provide data transmission rates in the order of multi-gigabits per second in order to satisfy the ever-increasing demand for high rate data communication. Unfortunately, 60 GHz radio is subject to severe path loss which limits its usability for long-range outdoor communication. In this work, we propose a multi-hop 60 GHz wireless network for outdoor communication where multiple full-duplex buffered relays are used to extend the communication range while providing end-to-end performance guarantees to the traffic traversing the network. We provide a cumulative service process characterization for the 60 GHz outdoor propagation channel with self-interference in terms of the moment generating function (MGF) of its channel capacity. We then use this characterization to compute probabilistic upper bounds on the overall network performance, i.e., total backlog and end-to-end delay. Furthermore, we study the effect of self-interference on the network performance and propose an optimal power allocation scheme to mitigate its impact in order to enhance network performance. Finally, we investigate the relation between relay density and network performance under a total power budget constraint. We show that increasing relay density may have adverse effects on network performance unless self-interference can be kept sufficiently small.