Building Transmission Backbone for Highway Vehicular Networks: Framework and Analysis

TL;DR

This paper proposes a stable multi-hop transmission backbone for highway vehicular networks, leveraging large, stable vehicles like trucks to improve communication reliability, throughput, and delay performance.

Contribution

It introduces a novel distributed protocol to build a backbone network based on stable vehicles and provides a queueing model to evaluate its performance.

Findings

Significant improvement in transmission reliability and throughput.

Reduced transmission interruptions and end-to-end delay.

Validation through extensive simulations showing enhanced performance.

Abstract

The highway vehicular ad hoc networks, where vehicles are wirelessly inter-connected, rely on the multi-hop transmissions for end-to-end communications. This, however, is severely challenged by the unreliable wireless connections, signal attenuation and channel contentions in the dynamic vehicular environment. To overcome the network dynamics, selecting appropriate relays for end-to-end connections is important. Different from the previous efforts (\emph{e.g.}, clustering and cooperative downloading), this paper explores the existence of stable vehicles and propose building a stable multi-hop transmission backbone network in the highway vehicular ad hoc network. Our work is composed of three parts. Firstly, by analyzing the real-world vehicle traffic traces, we observe that the large-size vehicles, \emph{e.g.}, trucks, are typically stable with low variations of mobility and stable channel condition of low signal attenuation; this makes their inter-connections stable in both connection time and transmission rate. Secondly, by exploring the stable vehicles, we propose a distributed protocol to build a multi-hop backbone link for end-to-end transmissions, accordingly forming a two-tier network architecture in highway vehicular ad hoc networks. Lastly, to show the resulting data performance, we develop a queueing analysis model to evaluate the end-to-end transmission delay and throughput. Using extensive simulations, we show that the proposed transmission backbone can significantly improve the reliability of multi-hop data transmissions with higher throughput, less transmission interruptions and end-to-end delay.