Lavinia Amorosi scite author profile

Bringing the cellular connectivity in rural zones is a big challenge, due to the large installation costs that are incurred when a legacy cellular network based on fixed Base Stations (BSs) is deployed. To tackle this aspect, we consider an alternative architecture composed of UAV-based BSs to provide cellular coverage, ground sites to connect the UAVs with the rest of the network, Solar Panels (SPs) and batteries to recharge the UAVs and to power the ground sites, and a ring of optical fiber links to connect the installed sites. We then target the minimization of the installation costs for the considered UAV-based cellular architecture, by taking into account the constraints of UAVs coverage, SPs energy consumption, levels of the batteries and the deployment of the optical ring. After providing the problem formulation, we derive an innovative methodology to ensure that a single ring of installed optical fibers is deployed. Moreover, we propose a new algorithm, called DIARIZE, to practically tackle the problem. Our results, obtained over a set of representative rural scenarios, show that DIARIZE performs very close to the optimal solution, and in general outperforms a reference design based on fixed BSs.

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Optimal Energy Management of UAV-Based Cellular Networks Powered by Solar Panels and Batteries: Formulation and Solutions

Amorosi

Chiaraviglio

Galán-Jiménez

2019

IEEE Access

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We focus on the problem of managing the energy consumption of a cellular network tailored to cover rural and low-income areas. The considered architecture exploits Unmanned Aerial Vehicles (UAVs) to ensure wireless coverage, as well as Solar Panels (SPs) and batteries installed in a set of ground sites, which provides the energy required to recharge the UAVs. We then target the maximization of the energy stored in the UAVs and in the ground sites, by ensuring the coverage of the territory through the scheduling of the UAV missions over space and time. After providing the problem formulation, we face its complexity by proposing a decomposition-based approach and by designing a brand-new genetic algorithm. The results, obtained over a set of representative case studies, reveal that there exists a trade-off between the UAVs battery level, the ground sites battery level, and the level of coverage. In addition, both the decomposed version and the genetic algorithm perform sufficiently close to the integrated model, with a strong improvement in the computation times.INDEX TERMS Energy management, mixed integer linear programming, renewable energy sources, Unmanned Aerial Vehicles, UAV mission scheduling, cellular networks.

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Optimal Design of 5G Networks in Rural Zones with UAVs, Optical Rings, Solar Panels and Batteries

Chiaraviglio

Amorosi

Bléfari-Melazzi

et al. 2018

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Coordinating drones with mothership vehicles: The mothership and drone routing problem with graphs

Amorosi

Puerto

Valverde

2021

Computers & Operations Research

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Lavinia Amorosi

Energy-Efficient Mission Planning of UAVs for 5G Coverage in Rural Zones

Minimum Cost Design of Cellular Networks in Rural Areas With UAVs, Optical Rings, Solar Panels, and Batteries

Optimal Energy Management of UAV-Based Cellular Networks Powered by Solar Panels and Batteries: Formulation and Solutions

Optimal Design of 5G Networks in Rural Zones with UAVs, Optical Rings, Solar Panels and Batteries

Coordinating drones with mothership vehicles: The mothership and drone routing problem with graphs

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