基于光纤感知的RFID被动标签能量最大化后向散射设计

Pub Date : 2022-01-01 DOI:10.36244/icj.2022.4.7
Amus Chee Yuen Goay, Deepak Mishra, Aruna Seneviratne
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引用次数: 1

摘要

射频识别(RFID)无源标签是一种能量可持续性高的无线通信设备,它利用入射射频(RF)信号对其信息进行反向散射。研究了反向散射通信(BackCom)网络中最优负载阻抗选择下的输出负载功率最大化问题。所考虑的BackCom系统包括向下行链路中的无源标签广播未调制载波的读取器。标签在上行链路中通过二进制移幅键控(BASK)调制将其信息信号反向散射到阅读器。在满足最小误码率(BER)要求和标签灵敏度约束的前提下,通过联合优化反射系数,提出了平均输出负载功率最大化问题。为了简化问题,我们将BER约束转化为调制指数约束,并将4变量问题简化为2变量凸优化问题。利用Karush-Kuhn-Tucker (KKT)条件,设计了一种算法,以获得使输出负载功率最大化的全局最优反射系数的封闭表达式。仿真结果揭示了信息位概率、标签灵敏度约束和误码率对可实现的平均负载功率的影响。大约16%的总体增益表明我们提出的设计的实用性。
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BER-Aware Backscattering Design for Energy Maximization at RFID Passive Tag
AbsThe radio frequency identification (RFID) passive tag is wireless communication device with high energy sustainability, such that it uses the incident radio frequency (RF) signal to backscatter its information. This paper investigates the output load power maximization with optimal load impedances selection in the backscatter communication (BackCom) network. The considered BackCom system comprises a reader broadcasting an unmodulated carrier to the passive tag in the downlink. The tag backscatters its information signal to the reader with binary amplitude-shift keying (BASK) modulation in the uplink. We formulated an average output load power maximization problem by jointly optimizing the reflection coefficients while satisfying the minimum bit error rate (BER) requirement and tag sensitivity constraint. To simplify the problem, we transform the BER constraint to the modulation index constraint and reduce the 4 variables problem to 2 variables convex optimization problem. Using the Karush-Kuhn-Tucker (KKT) conditions, we design an algorithm to obtain the closed-form expression for the global optimal reflection coefficients that maximize the output load power. The simulation results provide insight into the impact of the information bit probability, tag sensitivity constraint, and BER on the achievable average load power. An overall gain of around 16% signifies the utility of our proposed design.
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