Interference and Coverage Analysis of mmWave Inter-Vehicle Broadcast with Directional Antennas

TL;DR

This paper analyzes the performance of mmWave V2V broadcast in vehicular networks, focusing on interference, coverage, and the effects of directional antennas, providing insights for protocol design.

Contribution

It offers a systematic mathematical analysis of mmWave V2V broadcast considering propagation, interference, and antenna effects, which was less explored before.

Findings

Optimal beamwidth range maximizes coverage

Carrier sensing range significantly impacts network performance

Interference and blockage critically influence broadcast success

Abstract

Thanks to the availability of large bandwidth and high-gain directional antennas at the millimeter-wave (mmWave) bands, mmWave communications have been considered as one of the primary solutions to meet the high data rates needs in vehicular networks. Unicast in mmWave vehicle-to-vehicle (V2V) communications has been well-studied, but much less attention has been paid to V2V broadcast which is required by many V2V applications such as active safety. To fill the gap, this paper systematically investigates mmWave V2V broadcast by considering the unique properties of mmWave signal propagation in V2V environments as well as the impacts of directional antennas and interference. Based on widely-accepted, high-fidelity system models, we mathematically analyze the receiver-side signal-to-interference-plus-noise-ratio (SINR) and broadcast coverage, and we study the impacts of blockage, inter-vehicle distance, vehicle density and beam pattern. Through comprehensive numerical analysis, we find out that, instead of a single unique optimal beamwidth, there exists an optimal range of beamwidth, in which the beamwidths have similar performance and can maximize the coverage. We also find out that the selection of carrier sensing range plays an important role as it highly influences the performance of the whole vehicular networks. Our analysis provides unique insight into mmWave V2V broadcast, and it sheds light on designing effective V2V broadcast protocols.