计算机科学
基站
人工智能
强化学习
高效能源利用
信道状态信息
资源配置
分布式计算
资源管理(计算)
频道(广播)
剪裁(形态学)
能源消耗
国家(计算机科学)
马尔可夫决策过程
能量(信号处理)
增强学习
实时计算
蜂窝网络
资源(消歧)
数学优化
最优化问题
动态规划
动作选择
非线性系统
电信线路
方案(数学)
非线性规划
计算机工程
计算复杂性理论
作者
Mahmoud M. Salim,Khaled M. Rabie,Ali H. Muqaibel
标识
DOI:10.1109/jiot.2025.3623306
摘要
Reconfigurable intelligent surfaces (RISs) enhance unmanned aerial vehicles (UAV)-assisted communication by extending coverage, improving efficiency, and enabling adaptive beamforming. This paper investigates a multiple-input single-output system where a base station (BS) communicates with multiple single-antenna users through a UAV-assisted RIS, dynamically adapting to user mobility to maintain seamless connectivity. To extend UAV-RIS operational time, we propose a hybrid energy-harvesting resource allocation (HERA) strategy that leverages the irregular RIS ON/OFF capability while adapting to BS-RIS and RIS-user channels. The HERA strategy dynamically allocates resources by integrating non-linear radio frequency energy harvesting (EH) based on the time-switching (TS) approach and renewable energy as a complementary source. A non-convex mixed-integer nonlinear programming problem is formulated to maximize EH efficiency while satisfying quality-of-service, power, and energy constraints under channel state information and hardware impairments. The optimization jointly considers BS transmit power, RIS phase shifts, TS factor, UAV trajectory, and RIS element selection as decision variables. To solve this problem, we introduce the energy-efficient deep deterministic policy gradient (EE-DDPG) algorithm. This deep reinforcement learning (DRL)-based approach integrates action clipping and softmax-weighted Q-value estimation to mitigate estimation errors. Simulation results demonstrate that the proposed HERA method significantly improves EH efficiency, reaching up to 85.8% and 69.8% in single-user and multi-user scenarios, respectively, contributing to extended UAV operational time. Additionally, the proposed EE-DDPG model outperforms existing DRL algorithms while maintaining practical computational complexity.
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