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通过基于可重构智能表面(RIS)的传感和自适应功率聚焦实现可持续太赫兹无线信息与能量传输:迈向绿色6G物联网

Sustainable THz SWIPT via RIS-Enabled Sensing and Adaptive Power Focusing: Toward Green 6G IoT.

作者信息

Enahoro Sunday, Ekpo Sunday Cookey, Uko Mfonobong, Elias Fanuel, Unnikrishnan Rahul, Alabi Stephen, Olasunkanmi Nurudeen Kolawole

机构信息

Communication and Space Systems Engineering Research Team, Manchester Metropolitan University, Manchester M1 5GD, UK.

Research and Development Engineering, SmOp CleanTech, Manchester M40 8WN, UK.

出版信息

Sensors (Basel). 2025 Jul 23;25(15):4549. doi: 10.3390/s25154549.

DOI:10.3390/s25154549
PMID:40807716
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12349027/
Abstract

Terahertz (THz) communications and simultaneous wireless information and power transfer (SWIPT) hold the potential to energize battery-less Internet-of-Things (IoT) devices while enabling multi-gigabit data transmission. However, severe path loss, blockages, and rectifier nonlinearity significantly hinder both throughput and harvested energy. Additionally, high-power THz beams pose safety concerns by potentially exceeding specific absorption rate (SAR) limits. We propose a sensing-adaptive power-focusing (APF) framework in which a reconfigurable intelligent surface (RIS) embeds low-rate THz sensors. Real-time backscatter measurements construct a spatial map used for the joint optimisation of (i) RIS phase configurations, (ii) multi-tone SWIPT waveforms, and (iii) nonlinear power-splitting ratios. A weighted MMSE inner loop maximizes the data rate, while an outer alternating optimisation applies semidefinite relaxation to enforce passive-element constraints and SAR compliance. Full-stack simulations at 0.3 THz with 20 GHz bandwidth and up to 256 RIS elements show that APF (i) improves the rate-energy Pareto frontier by 30-75% over recent adaptive baselines; (ii) achieves a 150% gain in harvested energy and a 440 Mbps peak per-user rate; (iii) reduces energy-efficiency variance by half while maintaining a Jain fairness index of 0.999;; and (iv) caps SAR at 1.6 W/kg, which is 20% below the IEEE C95.1 safety threshold. The algorithm converges in seven iterations and executes within <3 ms on a Cortex-A78 processor, ensuring compliance with real-time 6G control budgets. The proposed architecture supports sustainable THz-powered networks for smart factories, digital-twin logistics, wire-free extended reality (XR), and low-maintenance structural health monitors, combining high-capacity communication, safe wireless power transfer, and carbon-aware operation for future 6G cyber-physical systems.

摘要

太赫兹(THz)通信以及同时进行的无线信息与功率传输(SWIPT)有潜力为无电池的物联网(IoT)设备供电,同时实现多千兆位数据传输。然而,严重的路径损耗、障碍物以及整流器非线性显著阻碍了吞吐量和收集到的能量。此外,高功率太赫兹波束可能会超过特定吸收率(SAR)限制,从而引发安全问题。我们提出了一种传感自适应功率聚焦(APF)框架,其中可重构智能表面(RIS)嵌入了低速率太赫兹传感器。实时反向散射测量构建了一个空间地图,用于对以下方面进行联合优化:(i)RIS相位配置,(ii)多音SWIPT波形,以及(iii)非线性功率分配比。加权最小均方误差内循环使数据速率最大化,而外部交替优化应用半定松弛来强制实施无源元件约束并确保符合SAR标准。在0.3太赫兹、20吉赫兹带宽以及多达256个RIS元件的全栈模拟表明,APF:(i)相较于最近的自适应基线,将速率-能量帕累托前沿提高了30 - 75%;(ii)收集到的能量增益达到150%,每个用户的峰值速率达到440兆比特每秒;(iii)将能量效率方差减半,同时保持0.999的 Jain公平性指数;(iv)将SAR限制在1.6瓦/千克,比IEEE C95.1安全阈值低20%。该算法在七次迭代中收敛,并且在Cortex - A78处理器上的执行时间不到3毫秒,确保符合6G实时控制预算。所提出的架构支持用于智能工厂、数字孪生物流、无线扩展现实(XR)以及低维护结构健康监测器的可持续太赫兹供电网络,为未来的6G网络物理系统结合了高容量通信、安全的无线功率传输以及碳感知操作。

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