Frequency Selective Surfaces for Reduced Specular Reflection under Oblique Incidence at 240 GHz

2023 17th European Conference on Antennas and Propagation (EuCAP) Pub Date : 2023-03-26 DOI:10.23919/EuCAP57121.2023.10133207

S. Brandl, Adrian Diepolder, Mario Mueh, C. Damm, C. Waldschmidt

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引用次数: 1

Abstract

As the alignment of a feed antenna to a steerable reflectarray becomes increasingly complicated at upper mm-wave frequencies, illuminating the structure from the far field is desirable. Simultaneously, the required fabrication precision makes large arrays expensive, effectively limiting the size. Consequently, spill-over feed radiation results in specular reflections, degrading the array’s far-field pattern. To mitigate these undesired reflections, planar periodic structures can be employed to implement spatial filtering. Three designs that reduce specular reflections of a planar surface, caused by an obliquely-incident wave at 240 GHz, are proposed. Additional to standard evaluation of the absorptivity per unit cell, this paper examines the suppression mechanism by studying the scattered far field of size-limited structures. To verify each design, the frequency dependency of the specular reflection and the far-field pattern of a small array are measured. In accordance with simulations, two polarization-maintaining variants feature 10 dB attenuation, whereas a mode-converting design achieves 23 dB.

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240 GHz斜入射下减少镜面反射的频率选择表面

由于在高毫米波频率下馈源天线与可操纵反射射线的对准变得越来越复杂，因此需要从远场照射结构。同时，所需的制造精度使得大型阵列昂贵，有效地限制了尺寸。因此，溢出馈电辐射导致镜面反射，降低了阵列的远场模式。为了减轻这些不希望的反射，可以采用平面周期结构来实现空间滤波。提出了三种减小240 GHz斜入射波对平面镜面反射的设计方案。在对单位细胞吸光率进行标准评价的基础上，本文通过研究尺寸受限结构的散射远场来探讨其抑制机理。为了验证每种设计，测量了镜面反射的频率依赖性和小阵列的远场方向图。根据仿真，两种保持极化的变体具有10 dB的衰减，而模式转换设计达到23 dB。

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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2023 17th European Conference on Antennas and Propagation (EuCAP)

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