Photonic-Crystal-Resonator-Based Corner Reflector With Angle-of-Arrival Sensing

IF 2.3 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC IEEE journal of radio frequency identification Pub Date : 2023-08-04 DOI:10.1109/JRFID.2023.3302009

Ali Alhaj Abbas;Yixiong Zhao;Jan C. Balzer;Klaus Solbach;Thomas Kaiser

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引用次数: 1

Abstract

In this paper, we propose a Photonic Crystal (PhC) resonator based corner reflector for sensing the Angle-of-Arrival (AoA) of the incident wave from an interrogator. The sensor is constructed of joining a flat metal plate with a one-dimensional PhC resonator at an angle of 90°. The PhC resonator is designed by inserting a defect layer between two quarter-wave Bragg mirrors in order to create a deep notch in the backscattering. While the PhC resonator provides unique spectral signatures in the “specular direction” related to AoA (i.e., by shifting the notch position), the corner configuration allows the back-scattering of these signatures to the direction of the interrogator. As a proof of concept, EM simulation and measurement are performed in W-band on a 40-mm squared PhC resonator perpendicularly joined with a same size metal plate. Based on signatures, a resolution of less than 6° can be achieved in the angular range −35° to 35°. Due to the corner configuration that allows a high Radar Cross Section (RCS), the proposed sensor shows the potential of sensing the AoA at long reading ranges.

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基于光子晶体谐振器的到达角传感角反射器

在本文中，我们提出了一种基于光子晶体（PhC）谐振器的角反射器，用于感测来自询问器的入射波的到达角（AoA）。该传感器由一块平面金属板与一个角度为90°的一维PhC谐振器连接而成。PhC谐振器是通过在两个四分之一波布拉格反射镜之间插入缺陷层来设计的，以便在后向散射中产生深凹口。虽然PhC谐振器在与AoA相关的“镜面方向”上提供了独特的光谱特征（即，通过移动凹口位置），但拐角配置允许这些特征向后散射到询问器的方向。作为概念验证，在W波段中，在与相同尺寸的金属板垂直连接的40mm平方的PhC谐振器上进行EM模拟和测量。根据特征，在−35°至35°的角度范围内可以实现小于6°的分辨率。由于转角配置允许高雷达截面积（RCS），所提出的传感器显示出在长读数范围内感应AoA的潜力。

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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IEEE journal of radio frequency identification

CiteScore

5.70

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