Throughput Maximization for Energy Harvesting based Relay Cooperative Backscattering Transmission

2021 IEEE International Conference on Communications Workshops (ICC Workshops) Pub Date : 2021-06-01 DOI:10.1109/ICCWorkshops50388.2021.9473528

Wen-Jing Wang, K. Xu, Li Zhen, Keping Yu, A. Bashir, S. Garg

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引用次数: 2

Abstract

In this paper, we develop a time allocation strategy that enhances transmission efficiency of small-size Internet of Mobile Things (IoMT) devices by relaying the information backscattered from user. The system works in a slotted fashion, where each transmission slot is divided into two phases. Specifically, in phase one, user backscatters downlink signals from power beacon (PB) and relay harvests the radio frequency (RF) energy from signal backscattered by user and that transmitted by PB. In phase two, relay forwards the decoded information to destination with harvested RF energy. We formulate the optimization problem and develop an optimal time allocation strategy maximizing throughput considering adaptively adjusted backscattering coefficient and battery capacity constraint at relay. We investigate the effect of transmit power and relay location on the throughput for infinite/finite battery capacity scenario, respectively. Numerical results verify that the proposed time allocation strategy outperforms that with fixed backscattering coefficient.

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基于能量收集的中继协同后向散射传输吞吐量最大化

在本文中，我们开发了一种时间分配策略，通过中继来自用户的反向散射信息来提高小型移动物联网设备的传输效率。该系统以插槽方式工作，其中每个传输插槽分为两个阶段。具体来说，在第一阶段，用户反向散射来自功率信标(PB)的下行信号，中继从用户反向散射的信号和PB发射的信号中收集射频(RF)能量。在第二阶段，中继利用收集到的射频能量将解码的信息转发到目的地。考虑自适应调整后向散射系数和继电器的电池容量约束，提出了优化问题，并制定了最大吞吐量的最优时间分配策略。我们分别研究了无限/有限电池容量情况下，发射功率和中继位置对吞吐量的影响。数值结果验证了所提出的时间分配策略优于固定后向散射系数的时间分配策略。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2021 IEEE International Conference on Communications Workshops (ICC Workshops)

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