Low‐altitude UAV air‐ground propagation channel measurement and analysis in a suburban environment at 3.9 GHz

Cui, Zhuangzhuang; Briso-Rodríguez, César; Guan, Ke; Matolak, David W.; Calvo-Ramírez, César; Ai, Bo; Zhang, Zhong

doi:10.1049/iet-map.2019.0067

Cited by 24 publications

(14 citation statements)

References 19 publications

(22 reference statements)

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“…In [14], the ABS network employs both ultra-high frequency (UHF) and S-bands to provide connectivity to ground users, thus combining the advantages of small path loss in low frequency bands with that of large bandwidth in high frequency bands. Measurements results conducted in rural, suburban, and urban areas are shown with horizontal distance up to 70 Km from the airship and altitude up to 950 m. Similarly, [15] reports measurements carried out at 3:9 GHz in suburban environment with an omnidirectional antenna installed on a small UAV flying at an altitude of 40 m. The results of LSP and SSP from the measurements show reasonable agreement when compared with ray tracing simulations for the same scenario. There are several MIMO based UAV channel models, which can be found in [10]- [12].…”

Section: B Relevant Workmentioning

confidence: 54%

Aerial Base Station Assisted Cellular Communication: Performance and Trade-Off

Sharma¹,

Kumar

Pervaiz

et al. 2021

IEEE Trans. Netw. Sci. Eng.

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The use of Aerial Base Stations (ABSs) has received a great deal of attention in academia and industry as a means to support the cellular communication traffic growth. In this article, we focus on obtaining the optimal altitude of an ABS using two criteria -maximum cell coverage area and minimum Symbol Error Rate (SER). Our study is done by using a probabilistic airto-ground channel model, developed for low altitude aerial platforms via simulations on a commercial ray tracing software, for different scenarios like Urban High Rise, Urban, and Suburban. The probability distributions of the received power of the ground users and of the power delay profile at optimal ABS altitude are provided as a function of the size of the cell area. For the SER analysis, we present a system model based on Generalized Frequency Division Multiplexing (GFDM), in a time-frequency grid that is compatible with Long Term Evolution, by implementing parameters for low latency communication at the physical layer. The impact of "Better than Nyquist" pulses on the GFDM system is evaluated in terms of SER performance. From the presented results, a significant improvement is demonstrated compared to the traditional Nyquist pulses.

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Section: B Relevant Workmentioning

confidence: 54%

Aerial Base Station Assisted Cellular Communication: Performance and Trade-Off

Sharma¹,

Kumar

Pervaiz

et al. 2021

IEEE Trans. Netw. Sci. Eng.

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“…The FSPL model describes an ideal radio condition between a transmitting and a receiving antenna, where only LOS link exists without other sources of scattering, diffraction, or reflection [ 25 ]. It is one of the commonly used models for characterization of the ground-to-air radio propagation [ 26 ]. Therefore, this model is used to determine path loss in the communication from surface devices to the UAV based on Equation ( 3 ) [ 25 ].…”

Section: Proposed Communication Modes and Solution Componentsmentioning

confidence: 99%

Prototype Design and Experimental Evaluation of Autonomous Collaborative Communication System for Emerging Maritime Use Cases

Pokorny

Saafi

et al. 2021

Sensors

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Automated systems have been seamlessly integrated into several industries as part of their industrial automation processes. Employing automated systems, such as autonomous vehicles, allows industries to increase productivity, benefit from a wide range of technologies and capabilities, and improve workplace safety. So far, most of the existing systems consider utilizing one type of autonomous vehicle. In this work, we propose a collaboration of different types of unmanned vehicles in maritime offshore scenarios. Providing high capacity, extended coverage, and better quality of services, autonomous collaborative systems can enable emerging maritime use cases, such as remote monitoring and navigation assistance. Motivated by these potential benefits, we propose the deployment of an Unmanned Surface Vehicle (USV) and an Unmanned Aerial Vehicle (UAV) in an autonomous collaborative communication system. Specifically, we design high-speed, directional communication links between a terrestrial control station and the two unmanned vehicles. Using measurement and simulation results, we evaluate the performance of the designed links in different communication scenarios and we show the benefits of employing multiple autonomous vehicles in the proposed communication system.

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“…For these reasons, dense urban scenarios have not been primarily targeted in previous studies, and A2G propagation measurements have been mainly carried out in rural/suburban environments [14], and often limited to few and quite short flying paths in clear visibility conditions to the pilot [15]- [17].…”

Section: Introductionmentioning

confidence: 99%

A Multi-Frequency Investigation of Air-to-Ground Urban Propagation Using a GPU-Based Ray Launching Algorithm

et al. 2021

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Unmanned Aerial Vehicles (UAV), also known as "drones", are attracting increasing attention as enablers for many technical applications and services, and this trend is likely to continue in the next future. When compared to conventional terrestrial communications, those making use of UAVs as base-or relaystations can definitely be more useful and flexible in reaction to specific events, like natural disasters and terrorist attacks. Among the many and different fields, UAV enabled communications emerge as one of the most promising solutions for next-generation mobile networks, with a special focus on the extension of coverage and capacity of mobile radio networks. Motivated by the air-to-ground (A2G) propagation conditions which are likely to be different than those experienced by traditional ground communication systems, this paper aims at investigating the narrowband properties of the air-to-ground channel for 5G communications and beyond by means of GPU accelerated ray launching simulations. Line of sight probability as well as path loss exponent and shadowing standard deviations are analysed for different UAV flight levels, frequencies and dense urban scenarios, and for different types of on board antennas. Thanks to the flexibility of the ray approach, the role played by the different electromagnetic interactions, namely reflection, diffraction and diffuse scattering, in the air-to-ground propagation process is also investigated. Computation time is reported as well to show that designing UAV communication networks and optimising their performances in a fast and reliable manner, might avoid exhausting -multiple -measurement campaigns.

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Low‐altitude UAV air‐ground propagation channel measurement and analysis in a suburban environment at 3.9 GHz

Cited by 24 publications

References 19 publications

Aerial Base Station Assisted Cellular Communication: Performance and Trade-Off

Aerial Base Station Assisted Cellular Communication: Performance and Trade-Off

Prototype Design and Experimental Evaluation of Autonomous Collaborative Communication System for Emerging Maritime Use Cases

A Multi-Frequency Investigation of Air-to-Ground Urban Propagation Using a GPU-Based Ray Launching Algorithm

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