Millimeter-Wave Directional Path Loss Models in the 26 GHz, 32 GHz, and 39 GHz Bands for Small Cell 5G Cellular System | Zendy

Mohsen Khalily | Zendy; Mir Ghoraishi | Zendy; Sona Taheri | Zendy; Sohail Payami | Zendy; Rahim Tafazolli | Zendy

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Millimeter-Wave Directional Path Loss Models in the 26 GHz, 32 GHz, and 39 GHz Bands for Small Cell 5G Cellular System

Author(s) -

Mohsen Khalily,

Mir Ghoraishi,

Sona Taheri,

Sohail Payami,

Rahim Tafazolli

Publication year - 2018

Publication title -

2022 16th european conference on antennas and propagation (eucap)

Language(s) - English

Resource type - Conference proceedings

DOI - 10.1049/cp.2018.0376

Subject(s) - path loss , extremely high frequency , wideband , fading , millimeter , radio spectrum , log distance path loss model , path (computing) , radio propagation , channel (broadcasting) , electronic engineering , computer science , physics , telecommunications , optics , engineering , wireless , computer network

This paper presents empirically-based large-scale propagation path loss models for small cell fifth generation (5G) cellular system in the millimeter-wave bands, based on practical propagation channel measurements at 26 GHz, 32 GHz, and 39 GHz. To characterize path loss at these frequency bands for 5G small cell scenarios, extensive wideband and directional channel measurements have been performed on the campus of the University of Surrey. Close-in reference (CI), and 3GPP path loss models have been studied, and large-scale fading characteristics have been obtained and presented.

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