Abstract
The exploitation of aerial base stations (A-BSs) in conjunction with terrestrial base stations (T-BSs) is envisioned as a promising solution to provide connectivity to devices and user-equipment (UE) in crowded situations (viz. in the sports event) and emergency situations (viz. in the disaster management). However, the use of A-BSs with existing terrestrial networks intensifies the inter-cell interference (ICI) to the devices and UEs, therefore leading to a degraded signal-to-interference-ratio (SIR). This paper addresses this issue by exploiting different radio access technology (RAT) (mmWave/microwave) for aerial and terrestrial networks. Indeed, the network connectivity is always a top priority for all applications. However, there are also some applications such as remote patient monitoring, and remote working, which requires both coverage and high data-rates. But, most of the existing research claims the trade-off between the coverage and the data-rate performance. Whereas this paper aims to improve coverage and rate simultaneously in an aerial-terrestrial networks by employing an optimal combination of mmWave and microwave RAT based on the proposed association strategy. The essential analysis of such an integrated network involves the evaluation of parameters based on the analytic model. Hence, this paper analytically obtains the coverage probability (CP) and average rate expressions for the proposed integrated aerial-terrestrial networks. The analysis is supported by probabilistic models-based simulations that agree closely with analytical results. The results claim that the proposed model leads to improved performance in terms of both CP and average rate. Also, the paper provides parametric analysis for CP and rate with A-BSs height and A-BSs density to enable its practical implementation in 5G/6G technologies
Highlights
While the deployment of commercial 5th generation (5G) cellular network is underway in most countries, the research community is talking about the use-cases, requirements and enabling technologies of 6th generation (6G) cellular network [1], [2]
A visual picture of connectivity and interference impact on reference user equipment (UE) in a typical downlink aerial-terrestrial cellular network is shown in Fig. 1, where we have considered five aerial base stations (A-BSs), four terrestrial base stations (T-BSs), and a reference UE
Theorem 9: The average coverage probability (CP) contributed by A-BSs in an integrated aerial-terrestrial networks is defined as, PC,A = PC,A,L AL + PC,A,N AN, (21)
Summary
While the deployment of commercial 5th generation (5G) cellular network is underway in most countries, the research community is talking about the use-cases, requirements and enabling technologies of 6th generation (6G) cellular network [1], [2]. This paper considers the mmWave RAT for A-BSs and microwave RAT for T-BSs. Whereas, a second challenge that has been identified is to provide good coverage and high data-rate performance for some specified use cases. Our work claims the improvement in coverage and the data-rate of the downlink aerial-terrestrial network by employing an optimal combination of mmWave and microwave RAT based on the proposed association strategy. Whereas the work presented in this paper considers an integrated mmWave and microwave framework for aerial-terrestrial networks. Whereas the work presented in this paper claims the improvement in both coverage and the data-rate of the downlink aerial-terrestrial networks. The work in [29] considers a downlink aerial-terrestrial network comprising of T-BS and A-BS, where both stations operate at microwave frequency and investigate coverage and rate performance. We assume that the terrestrial links experience Rayleigh fading, and we consider an omnidirectional antenna model at T-BSs
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