Double Directional Channel Measurements for THz Communications in an Urban Environment

TL;DR

This paper presents the first outdoor double-directional THz channel measurements in an urban environment, revealing many significant propagation directions and providing fundamental parameters for future THz communication system design.

Contribution

It introduces the first outdoor double-directional THz channel measurements in the 141-148.5 GHz range, using RFoF-based sounding over 100 meters in urban scenarios.

Findings

Large number of directions carry significant energy

Fundamental parameters identified for THz channel modeling

Measurements conducted in the 141-148.5 GHz band

Abstract

While mm-wave systems are a mainstay for 5G communications, the inexorable increase of data rate requirements and user densities will soon require the exploration of next-generation technologies. Among these, Terahertz (THz) band communication seems to be a promising direction due to availability of large bandwidth in the electromagnetic spectrum in this frequency range, and the ability to exploit its directional nature by directive antennas with small form factors. The first step in the analysis of any communication system is the analysis of the propagation channel, since it determines the fundamental limitations it faces. While THz channels have been explored for indoor, short-distance communications, the channels for {\em wireless access links in outdoor environments} are largely unexplored. In this paper, we present the - to our knowledge - first set of double-directional outdoor propagation channel measurements for the THz band. Specifically, the measurements are done in the 141 - 148.5 GHz range, which is one of the frequency bands recently allocated for THz research by the Federal Communication Commission (FCC). We employ double directional channel sounding using a frequency domain sounding setup based on RF-over-Fiber (RFoF) extensions for measurements over 100 m distance in urban scenarios. An important result is the surprisingly large number of directions (i.e., direction-of-arrival and direction-of-departure pairs) that carry significant energy. More generally, our results suggest fundamental parameters that can be used in future THz Band analysis and implementations.