Abstract
Multiple unmanned aerial vehicles (UAVs) can compensate for the performance deficiencies of a single UAV in multi-access edge computing (MEC) systems, thus providing improved offloading services to user equipments (UEs). In multi-UAV enabled MEC systems, the offloading strategy and UAVs' trajectories affect the fairness of both UEs and UAVs, which affects the UE experience and UAVs' existence durations. Therefore, we investigate fairness-aware offloading and trajectory optimization in the system. To ensure fairness of energy consumptions (ECs) for both UEs and UAVs, we minimize the weighted sum of the maximum EC among UEs and the maximum EC among UAVs subject to the task delay, the offloading strategy and UAVs' trajectories constraints. Despite the non-convexity of the original formulated joint optimization problem, we transform the problem into two sub-problems and solve them one by one. Finally, an iterative optimization algorithm is proposed to alternately optimize the offloading strategies and the UAVs' trajectories. Simulation results show that the proposed algorithm can effectively reduce both the maximum EC among UEs and the maximum EC among UAVs and ensure the fairness of both the UEs and UAVs.
Highlights
In recent years, smart mobile applications [1]–[4] have brought convenience to people’s lives, and brought great challenges to user equipments (UEs)
CONTRIBUTIONS AND ORGANIZATION In this paper, we study a multi-unmanned aerial vehicles (UAVs) enabled Multi-Access edge computing (MEC) system where multiple UAVs roaming in the area of interest help UEs complete the computing tasks
In order to make the weighted ECs of the UEs and the weighted ECs of the UAVs on the order of magnitude as close as possible, and to optimize the ECs of both UEs and UAVs better, we compare the UE’s local computing energy consumptions with the UAVs’
Summary
Smart mobile applications (e.g., speech recognition, augmented reality, sensing data processing) [1]–[4] have brought convenience to people’s lives, and brought great challenges to user equipments (UEs). These smart applications are computation-intensive and resource-hungry applications that require large amounts of computing resources and energy consumptions (ECs). This service method mainly has the following disadvantages. It is difficult for fixed servers to be deployed in the areas where there are computing requirements but the BS/AP is difficult to set up.
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