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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Cellular-connected UAV in Next-Generation Wireless Networks

Cherif, Nesrine 01 November 2022 (has links)
Unmanned aerial vehicle (UAV) technology has gained a great interest in communication systems due to its ability to host a cellular base station (BS) and thus act as an aerial BS (UAV-BS). The inheritance of mobility in the airspace makes the deployment of UAV-BSs flexible and agile aiming to mainly complement the terrestrial network, extend its coverage, and serve as a capacity injector in high-throughput demand scenarios. Besides, a UAV can also act as an aerial user (UAV-UE) for various use cases, such as aerial data collection and cargo delivery. Such UAV-UE missions need reliable cellular communication links in order to safely operate in beyond visual line-of-sight (BVLoS). Since terrestrial networks were not primarily designed to serve aerial users, due to their down-tilted BS antennas, re-coursing solely to these networks for aerial users’ cellular connectivity might not be a viable approach as a long-term solution. Alternatively, deploying UAV-BSs in this context can substantially improve both aerial and terrestrial users coverage and capacity. One of the challenging issues is how to characterize the UAV-UE performance in integrated aerial/terrestrial networks, called vertical heterogeneous networks (VHetNets). First, we thoroughly study the aerial user’s performance in terms of coverage probability in a VHetNets setup. Under a more realistic system model, we revisit the coverage and throughput performances of an aerial user in VHetNets, considering LoS and non-LoS (NLoS) transmissions and under different spectrum sharing policies among separate aerial and terrestrial networks. Some insights have been concluded on the integration of aerial BSs and UAV-UEs with the existing terrestrial network. Specifically, optimal positioning of UAV-BSs for maximized aerial users coverage was investigated for various aerial users distribution and spectrum allocations. Moreover, visioning that UAV technology will revolutionize the cargo delivery industry, we proposed a new concept of 3D aerial highways, which designs coordinated routes for a massive number of UAVs used mainly for delivery purposes. In this context, multiple network technologies were proposed and discussed to guarantee the cellular connectivity of cargo-UAVs in 3D aerial highways. For the particular case of connectivity supported by terrestrial cellular networks, an optimal energy-efficient and low-handoff trajectory planning for a cargo-UAV mission was proposed, with respect to disconnectivity constraints. Consequently, associated design guidelines and recommendations have been drawn. Leveraging reinforcement learning (RL) tools, we proposed a novel algorithm for path planning and cell association for the cargo-UAV that maximizes its cellular service reliability and minimizes the handoff events. Finally, we introduced a new paradigm, intermittently tethered UAV (iTUAV), as a trade-off between mobility and energy availability for providing cellular connectivity in temporary events.

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