Radio propagation modeling methods and tools

Katsuyuki Haneda, Richard Rudd, Enrico Vitucci, Danping He, Pekka Kyösti, Fredrik Tufvesson, Sana Salous, Yang Miao, Wout Joseph, Emmeric Tanghe

Research output: Chapter in Book/Report/Conference proceedingChapterScientific

11 Citations (Scopus)
463 Downloads (Pure)

Abstract

This chapter provides overview of fundamental definitions, tools and new methods towards improved channel modeling reported in the Co-operation in Science and Technology (COST)-Inclusive Radio Communications (IRACON) Action for future wireless communications and networks. The overview first covers definitions of propagation environments as they determine most relevant propagation mechanisms to consider and model, and furthermore, guide approach to channel modeling methods. This chapter then introduces new insights into popular approaches of channel modeling, i.e., site-specific and geometry-based stochastic channel modeling, where the latter particularly features canonical and standardized channel modeling approaches taken by the 3rd Generation Partnership Project (3GPP), COST, and International Telecommunication Union (ITU) communities. Finally, this chapter shed lights on new modeling approaches to small-scale radio propagation behaviors, covering plane wave propagation paths and distributed diffuse scattering.

Original languageEnglish
Title of host publicationInclusive Radio Communications for 5G and Beyond
PublisherAcademic Press
Pages7-48
Number of pages42
ISBN (Electronic)978-0-12-820581-5
DOIs
Publication statusPublished - 1 Jan 2021
MoE publication typeB2 Book section

Keywords

  • Dense multipath models
  • Enhanced COST2100 channel model
  • Full-wave radio propagation models
  • Geometry-based stochastic channel models
  • ITU-R path loss models
  • Multipath clustering algorithms
  • Multipath estimation algorithms
  • Propagation environments
  • Ray-based models of wave propagation
  • Site-specific channel models

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