Litcius/Paper detail

Millimeter Wave and Sub-THz Indoor Radio Propagation Channel Measurements, Models, and Comparisons in an Office Environment

Yunchou Xing, Theodore S. Rappaport, Amitava Ghosh

2021IEEE Communications Letters154 citationsDOIOpen Access PDF

Abstract

This letter provides a comparison of indoor radio propagation measurements and corresponding channel statistics at 28, 73, and 140 GHz, based on extensive measurements from 2014–2020 in an indoor office environment. Side-by-side comparisons of propagation characteristics (e.g., large-scale path loss and multipath time dispersion) across a wide range of frequencies from the low millimeter wave band of 28 GHz to the sub-THz band of 140 GHz illustrate the key similarities and differences in indoor wireless channels. The measurements and models show remarkably similar path loss exponents over frequencies in both line-of-sight (LOS) and non-LOS (NLOS) scenarios, when using a one meter free space reference distance, while the multipath time dispersion becomes smaller at higher frequencies. The 3GPP indoor channel model overestimates the large-scale path loss and has unrealistic large numbers of clusters and multipath components per cluster compared to the measured channel statistics in this letter.

Topics & Concepts

Non-line-of-sight propagationDelay spreadMultipath propagationPath lossExtremely high frequencyLog-distance path loss modelChannel (broadcasting)Dispersion (optics)Radio spectrumComputer scienceAcousticsTelecommunicationsWirelessPhysicsOpticsMillimeter-Wave Propagation and ModelingAdvanced MIMO Systems OptimizationPower Line Communications and Noise