Energy-Efficient UAV Communication with Multiple GTs Based on Trajectory Optimization

Yu Xu,Dingcheng Yang,Laurie Cuthbert,Yapeng Wang,Lin Xiao

doi:10.1155/2018/5629573

Yu Xu, Dingcheng Yang + Show 3 more

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https://doi.org/10.1155/2018/5629573

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Abstract

Wireless communications with unmanned aerial vehicles (UAVs) is a promising technology offering potential high mobility and low cost. This paper studies a UAV-enabled communication system, in which a fixed-wing UAV is deployed to collect information from a group of distributed ground terminals (GTs). Considering the requirements for quality of service (QoS) (i.e., the throughput of each GT is above a given threshold) and GT scheduling, we maximize the energy efficiency (EE) of the UAV in bits/Joule by optimizing the UAV’s flight trajectory. In this paper, a mixed integer nonconvex optimization problem is formulated. As that is difficult to solve, we divide the formulated problem into two subproblems and apply standard linear programming (LP) and successive convex optimization techniques. We further propose an efficient iterative algorithm that jointly optimizes GT scheduling and the UAV’s trajectory. Moreover, we set two special cases as benchmarks to measure the performance of the proposed design. The numerical results show that our proposed design achieves much better performance than the other two benchmark designs.

Highlights

Unmanned aerial vehicles (UAVs) recently are attracting significant attention in many fields: they can be applied in many different scenarios, including surveillance, monitoring, mobile relays, and data collection [1]
It is observed that the UAV can achieve higher EE when it flies without considering quality of service (QoS) requirements, and the UAV’s EE is minimum when it adopts the method of average time allocation, which is in line with our expectations
We investigate the energy efficiency of a UAV wireless communication system with multiple ground terminals (GTs)

Summary

Introduction

Unmanned aerial vehicles (UAVs) recently are attracting significant attention in many fields: they can be applied in many different scenarios, including surveillance, monitoring, mobile relays, and data collection [1]. UAVs can provide line-of-sight (LoS) links and offer good link capacity. Due to their potential mobility, flexible deployment, and low cost, UAVs are available for many operations and applications, such as precision agriculture [2], search and rescue [3], and timely environment monitoring and disaster warning [4,5,6]. UAVs provide aerial platforms that can be widely applied in wireless communication systems, as they can provide the terrestrial-aerial communication service for terrestrial users in regions lacking terrestrial infrastructures or under overload conditions [13, 14]

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