Two‐Ray Reflection Resolution Algorithm for Planar Material Electromagnetic Property Measurement at the Millimeter‐Wave Bands

Zhang, Jiliang; Liao, Xi; Glazunov, Andrés Alayón; Shao, Yu; Wang, Yang; Chu, Xiaoli; Zhang, Jie

doi:10.1029/2019rs006944

Cited by 7 publications

(2 citation statements)

References 25 publications

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“…Moreover, the exact knowledge of our living environment, for example, shapes of trees and leaves, layered wall structures and their dielectric constants is essential to know the attenuation during wave‐object interaction, but it isn't always available or accessible and hence left as a challenge. Therefore, a great deal of work is still needed to characterize the scattering properties of many construction materials for the several mm‐wave and sub‐THz frequencies that are being proposed for beyond‐5G wireless systems (Possenti et al., 2020; Zhang et al., 2020).…”

Section: New Propagation Characteristicsmentioning

confidence: 99%

5G to 6G: A Paradigm Shift in Radio Channel Modeling

2022

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Since the publication of the special collection on Radio Channel Modeling for 5G Millimeter Wave Communications in the Built Environments new frequency bands, new antennas and new transmission techniques are being proposed to cope with the demanding requirements of beyond‐5G systems. In this commentary, we provide an overview of the new technology and on how it will impact on radiowave propagation characteristics, and the way radio channel models will be developed and used in the future.

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Section: New Propagation Characteristicsmentioning

confidence: 99%

5G to 6G: A Paradigm Shift in Radio Channel Modeling

2022

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“…To avoid any possible negative impact on the functionality and appearance of a room, a desirable indoor BS deployment is to integrate MIMO antenna arrays with interior walls [15], [16], which however will result in non-negligible coupling between MIMO antenna arrays and building materials [17]- [19]. Specifically, when an EM wave impinges on a wall surface, the intensity of the wall reflected wave can be measured by the reflection coefficient, which depends on the EM and physical properties of the wall material, i.e., its relative permittivity and thickness [20]- [25]. The wall reflected EM waves would be superposed with other EM waves, which may jointly influence the indoor wireless performance.…”

Section: Introductionmentioning

confidence: 99%

How Friendly Are Building Materials as Reflectors to Indoor LOS MIMO Communications?

Zhang

Chen

Yang

et al. 2020

IEEE Internet Things J.

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The tremendous popularity of internet of things (IoT) applications and wireless devices have prompted a massive increase of indoor wireless traffic. To further explore the potential of indoor IoT wireless networks, creating constructive interactions between indoor wireless transmissions and the built environments becomes necessary. The electromagnetic (EM) wave propagation indoors would be affected by the EM and physical properties of the building material, e.g., its relative permittivity and thickness. In this paper, we construct a new multipath channel model by characterising wall reflection (WR) for an indoor line-of-sight (LOS) single-user multiple-input multipleoutput (MIMO) system and derive its ergodic capacity in closedform. Based on the analytical results, we define the wireless friendliness of a building material based on the spatially averaged indoor capacity and propose a scheme for evaluating the wireless friendliness of building materials. Monte Carlo simulations validate our analytical results and manifest the significant impact of the relative permittivity and thickness of a building material on indoor capacity, indicating that the wireless friendliness of building materials should be considered in the planning and optimisation of indoor wireless networks. The outcomes of this paper would enable appropriate selection of wall materials during building design, thus enhancing the capacity of indoor LOS MIMO communications.

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