Ling Tan, Lei Sun, Boyuan Cao, Jingming Xia, Hai Xu
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引用次数: 0
Abstract
This article investigates a mobile edge computing (MEC) network assisted by multiple unmanned aerial vehicles (UAVs) to address the computational and offloading requirements for mobile intelligent terminals (MITs) within crowded venues. The objective is to tackle intricate task processing and diminish MITs' waiting times. Considering the randomness of task arrival at the MITs and the imbalance between the amount of data and computation for complex tasks, a dual-queue model with data cache queue and computation queue is proposed, with minimizing the weighted system total energy consumption and average delay as the optimization objectives. Lyapunov optimization theory is employed to convert the stochastic optimization problem into a deterministic one, and the initial deployment quantity and hovering position of the UAVs are determined by the density-based spatial clustering of applications with noise (DBSCAN) method with noise. Then PPO algorithm for MIT task, resource allocation, and UAV trajectory optimization. Numerical results display the proposed scheme can efficaciously diminish energy consumption and delay by 10% and 33% respectively, compared with the baseline scheme. This paper proposes a practical and feasible solution for stochastic computing offloading in UAV-assisted MEC, which fills the gap in existing research on regarding the consideration of complex task imbalances.
本文研究了由多架无人飞行器(UAV)辅助的移动边缘计算(MEC)网络,以满足拥挤场所内移动智能终端(MIT)的计算和卸载需求。其目标是处理复杂的任务并缩短移动智能终端的等待时间。考虑到任务到达 MIT 的随机性以及复杂任务的数据量和计算量之间的不平衡,提出了一个包含数据缓存队列和计算队列的双队列模型,并以最小化加权系统总能耗和平均延迟为优化目标。利用李亚普诺夫优化理论将随机优化问题转化为确定优化问题,并通过带噪声的基于密度的应用空间聚类(DBSCAN)方法确定无人机的初始部署数量和悬停位置。然后采用 PPO 算法进行 MIT 任务、资源分配和无人机轨迹优化。数值结果表明,与基线方案相比,所提出的方案能有效减少 10%的能耗和 33%的延迟。本文为无人机辅助飞行任务控制(MEC)中的随机计算卸载提出了一种切实可行的解决方案,填补了现有研究在考虑复杂任务不平衡方面的空白。
期刊介绍:
IET Communications covers the fundamental and generic research for a better understanding of communication technologies to harness the signals for better performing communication systems using various wired and/or wireless media. This Journal is particularly interested in research papers reporting novel solutions to the dominating problems of noise, interference, timing and errors for reduction systems deficiencies such as wasting scarce resources such as spectra, energy and bandwidth.
Topics include, but are not limited to:
Coding and Communication Theory;
Modulation and Signal Design;
Wired, Wireless and Optical Communication;
Communication System
Special Issues. Current Call for Papers:
Cognitive and AI-enabled Wireless and Mobile - https://digital-library.theiet.org/files/IET_COM_CFP_CAWM.pdf
UAV-Enabled Mobile Edge Computing - https://digital-library.theiet.org/files/IET_COM_CFP_UAV.pdf