RCS Reduction of 2×2 Microstrip Antenna Array Using All Dielectric Metasurface

2018 11th UK-Europe-China Workshop on Millimeter Waves and Terahertz Technologies (UCMMT) Pub Date : 2018-09-01 DOI:10.1109/UCMMT45316.2018.9015677

M. Al-Nuaimi, Yejun He

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Abstract

This paper proposes a method to reduce the radar cross section (RCS) of a 2×2 microstrip antenna array around 20 GHz. The presented design is based on reflection phase cancellation principle and uses an all dielectric unit cell. Two perforated unit cells with 0° and 180° reflection phases are used and their geometrical parameters are optimized carefully to have 180° ± 30° reflection phase difference between their reflection phases, which is required to realize the phase cancellation. A 2×2 microstrip array is designed at 20 GHz and the proposed unit cell is distributed around the antennas in Chessboard like surface. A clear monostatic RCS reduction is achieved from about 18 GHz to 27 GHz with low level backscattered EM wave in the half space in front of the antenna array under both normal and oblique incidence of far-field plane wave. In the presented technique, no metallic inclusions are used on the upper surface of the dielectric substrate next to the antenna array radiating elements. Compared to the previously published works which used metallic inclusions next to radiating elements, the presented design has less effect on the radiation characteristics of the antenna array.

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利用全介电超表面降低2×2微带天线阵的RCS

本文提出了一种降低2×2微带天线阵20 GHz左右雷达截面(RCS)的方法。该设计基于反射相位抵消原理，采用全介质单元电池。采用两个反射相位为0°和180°的穿孔单晶片，对其几何参数进行优化，使其反射相位相差180°±30°，从而实现相消。设计了一个20 GHz频率的2×2微带阵列，该阵列以棋盘状表面分布在天线周围。在远场平面波的正向和斜向入射下，天线阵前半空间的低电平后向散射电磁波均实现了从18 GHz到27 GHz的明显单稳态RCS降低。在本技术中，在靠近天线阵列辐射元件的介电基板的上表面不使用金属夹杂物。与以往在辐射元件旁放置金属夹杂物相比，本设计对天线阵辐射特性的影响较小。

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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2018 11th UK-Europe-China Workshop on Millimeter Waves and Terahertz Technologies (UCMMT)

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