Millimeter wave propagation in long corridors and tunnels—theoretical model and experimental verification

Liat Rapaport; Gad A. Pinhasi; Yosef Pinhasi

doi:10.3390/electronics9050707

Millimeter wave propagation in long corridors and tunnels—theoretical model and experimental verification

Liat Rapaport, Gad A. Pinhasi, Yosef Pinhasi

Ariel University

Research output: Contribution to journal › Article › peer-review

Abstract

The development of the Fifth-Generation (5G) of cellular communications considers bands in millimeter waves (MMW) for indoor, short-range links. The propagation of MMW is affected by atmospheric and weather conditions, specular reflections from surfaces, and the directivity of the antennas. The short wavelength enables utilization of a quasi-optical propagation model for the description of indoor multi-path scenarios. A study of MMW propagation in tunnels, long corridors, or canyons is carried out using ray-tracing to evaluate the link budget and group delay. The analysis considers radiation patterns of both transmitting and receiving antennas, deriving a criterion for the number of dominating rays. Error analysis demonstrates the convergence of the method, while using a finite number of reflected rays. Experiments in a small-scale tunnel model demonstrate the accuracy of the analysis.

Original language	English
Article number	707
Journal	Electronics (Switzerland)
Volume	9
Issue number	5
DOIs	https://doi.org/10.3390/electronics9050707
State	Published - May 2020

Keywords

5G
Indoor millimeter wave propagation
MMW
Ray tracing model

All Science Journal Classification (ASJC) codes

Control and Systems Engineering
Signal Processing
Hardware and Architecture
Computer Networks and Communications
Electrical and Electronic Engineering

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10.3390/electronics9050707

Cite this

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title = "Millimeter wave propagation in long corridors and tunnels—theoretical model and experimental verification",

abstract = "The development of the Fifth-Generation (5G) of cellular communications considers bands in millimeter waves (MMW) for indoor, short-range links. The propagation of MMW is affected by atmospheric and weather conditions, specular reflections from surfaces, and the directivity of the antennas. The short wavelength enables utilization of a quasi-optical propagation model for the description of indoor multi-path scenarios. A study of MMW propagation in tunnels, long corridors, or canyons is carried out using ray-tracing to evaluate the link budget and group delay. The analysis considers radiation patterns of both transmitting and receiving antennas, deriving a criterion for the number of dominating rays. Error analysis demonstrates the convergence of the method, while using a finite number of reflected rays. Experiments in a small-scale tunnel model demonstrate the accuracy of the analysis.",

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AB - The development of the Fifth-Generation (5G) of cellular communications considers bands in millimeter waves (MMW) for indoor, short-range links. The propagation of MMW is affected by atmospheric and weather conditions, specular reflections from surfaces, and the directivity of the antennas. The short wavelength enables utilization of a quasi-optical propagation model for the description of indoor multi-path scenarios. A study of MMW propagation in tunnels, long corridors, or canyons is carried out using ray-tracing to evaluate the link budget and group delay. The analysis considers radiation patterns of both transmitting and receiving antennas, deriving a criterion for the number of dominating rays. Error analysis demonstrates the convergence of the method, while using a finite number of reflected rays. Experiments in a small-scale tunnel model demonstrate the accuracy of the analysis.

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Millimeter wave propagation in long corridors and tunnels—theoretical model and experimental verification

Abstract

Keywords

All Science Journal Classification (ASJC) codes

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