Effects of Solar Radio Emissions on Outdoor Propagation Path Loss Models at 60 GHz Bands for Access/Backhaul Links and D2D Communications

TL;DR

This study investigates how solar radio emissions impact outdoor 60 GHz propagation path loss, revealing increased path loss during sunny conditions which affects 5G access, backhaul, and D2D communication coverage.

Contribution

It provides the first combined analytical and empirical analysis of solar radio emissions' effects on 60 GHz outdoor propagation models for 5G systems.

Findings

Solar radio emissions increase path loss exponent during sunny weather.

Path loss exponent increases by 9.0%-15.6% in hot, sunny conditions.

Coverage decreases in hot, sunny weather due to higher path loss.

Abstract

This paper presents analytical and empirical data documenting the effects of solar radio emissions on outdoor propagation path loss at 60 GHz bands. Both line-of-sight (LOS) and non-LOS scenarios were considered. The setup used in the empirical studies emulates the future fifth-generation cellular systems for both access and backhaul services, as well as for device-to-device communications. Based on the measurement data collected in sunny weather with intense solar activities, we developed large-scale propagation path loss models at 60 GHz, and observed the effects of solar radio emissions on the path loss data. It is shown that solar radio emission can decrease carrier-to-noise ratio, and that this translates into a corresponding increase in the path loss exponent (PLE) values for the large-scale propagation path loss channel models. Empirical data show that 9.0%-15.6% higher PLE values were observed in hot and sunny weather during the day (41{\deg}-42 {\deg}C) compared with the counterpart measurements taken at night in cool and clear weather (20{\deg}-38 {\deg}C). This translates into a corresponding decrease in 60 GHz radio coverage in hot and sunny weather during the day. The empirical data are closely corroborated by analytical estimates presented.