A novel FSS structure with high selectivity and excellent angular stability for 5G communication radome

2017 10th Global Symposium on Millimeter-Waves Pub Date : 2017-05-24 DOI:10.1109/GSMM.2017.7970275

Tianwu Li, Da Li, E. Li

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引用次数: 19

Abstract

A novel frequency selective surface structure (FSSs) with high selectivity and excellent angular stability is proposed in this paper. To improve the performance of the FSS especially in angular stability, the coupling of capacitive surface and inductive surface is employed to realize the miniaturization of the structural unit around 0.23λ. Furthermore, to enhance the passband of the FSS, a multi-layer FSS structure is adopted to form a 2nd-order filter. In addition, as a bandstop with a high suppression is demanded in the 5G communication, we introduce a “Jerusalem cross“ structure in the inductive surface layer ingeniously to add the LC series resonance which can realize a rapid decline in the passband edge. One significant feature of this FSS design is that the passband and stopband can be controlled by different parts of the structure respectively, which greatly improves the FSS stability. Finally, a novel FSS working at the center frequency of 28.5 GHz with a low-profile broadband and a high rejection stopband is designed. It still has a stable transmission performance, when the incident wave angle changes up to 60°. These results demonstrate that the proposed FSS is a good candidate for 5G communication radome.

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5G通信天线罩中具有高选择性和良好角稳定性的新型FSS结构

提出了一种具有高选择性和角稳定性的新型频率选择表面结构(fss)。为了提高FSS的性能，特别是在角稳定性方面，采用电容面和感应面耦合的方法，实现了结构单元在0.23λ附近的小型化。此外，为了增强FSS的通带，采用多层FSS结构形成二阶滤波器。此外，针对5G通信对高抑制带阻的要求，我们巧妙地在感应面层引入“耶路撒冷十字”结构，加入LC串联谐振，实现通带边缘的快速下降。该FSS设计的一个显著特点是通带和阻带可以由结构的不同部分分别控制，大大提高了FSS的稳定性。最后，设计了一种工作在28.5 GHz中心频率、低轮廓宽带和高抑制阻带的新型FSS。当入射波角度变化到60°时，仍然具有稳定的传输性能。这些结果表明，所提出的FSS是5G通信天线罩的良好候选者。

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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2017 10th Global Symposium on Millimeter-Waves

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