Lyapunov优化
计算机科学
计算卸载
移动边缘计算
能源消耗
云计算
数学优化
分布式计算
计算
最优化问题
任务(项目管理)
资源配置
边缘计算
李雅普诺夫函数
移动设备
随机优化
无线
能量最小化
缩小
强化学习
实时计算
网络拥塞
无线网络
能量(信号处理)
延迟(音频)
能源供应
梯度下降
GSM演进的增强数据速率
资源管理(计算)
高效能源利用
蜂窝网络
边缘设备
作者
Jianhua Liu,Xudong Zhang,Haitao Zhou,Xia Lei,Huiru Li,Xiaofan Wang
出处
期刊:Drones
[Multidisciplinary Digital Publishing Institute]
日期:2025-09-16
卷期号:9 (9): 653-653
被引量:1
标识
DOI:10.3390/drones9090653
摘要
The demand for low-latency computing from the Internet of Things (IoT) and emerging applications challenges traditional cloud computing. Mobile Edge Computing (MEC) offers a solution by deploying resources at the network edge, yet terrestrial deployments face limitations. Unmanned Aerial Vehicles (UAVs), leveraging their high mobility and flexibility, provide dynamic computation offloading for User Equipments (UEs), especially in areas with poor infrastructure or network congestion. However, UAV-assisted MEC confronts significant challenges, including time-varying wireless channels and the inherent energy constraints of UAVs. We put forward the Lyapunov-based Deep Deterministic Policy Gradient (LyDDPG), a novel computation offloading algorithm. This algorithm innovatively integrates Lyapunov optimization with the Deep Deterministic Policy Gradient (DDPG) method. Lyapunov optimization transforms the long-term, stochastic energy minimization problem into a series of tractable, per-timeslot deterministic subproblems. Subsequently, DDPG is utilized to solve these subproblems by learning a model-free policy through environmental interaction. This policy maps system states to optimal continuous offloading and resource allocation decisions, aiming to minimize the Lyapunov-derived “drift-plus-penalty” term. The simulation outcomes indicate that, compared to several baseline and leading algorithms, the proposed LyDDPG algorithm reduces the total system energy consumption by at least 16% while simultaneously maintaining low task latency and ensuring system stability.
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