Complementary Split Square Ring Resonator-Based Double Negative Metamaterial for C, X, and Ku bands Satellite Applications

2021 7th International Conference on Space Science and Communication (IconSpace) Pub Date : 2021-11-23 DOI:10.1109/iconspace53224.2021.9768309

I. Hossain, M. Samsuzzaman, M. Baharuddin, B. Bais, T. Alam, Mandeep Jit Singh

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Abstract

This study proposed an interlinked coupled split square ring resonator (SSRR) based metamaterial (MTM) unit cell. The double-negative (DNG) metamaterial characteristics are exhibited in C, X, and Ku microwave frequency bands. The proposed MTM unit cell contains six split square ring resonators (SSRR) where a horizontal metal bar is interlinked between the fourth and fifth SSRR and a vertical metal bar interlinks between the third and fifth SSRR. The perfect electric conductor (PEC) and Rogers- RT 5880 are used in the resonator and dielectric layer to design the MTM unit cell. The unit cell has a dimension of 10×10×1.57 mm3, and the thickness of the resonator layer and dielectric layer is 0.04 mm, 1.57 mm, respectively. The Computer Simulation Technology (CST Microwave Studio 2019) software is used to extract effective parameters then the finite element method (FEM) is used to verify the unit cell’s performance. Due to symmetrical structure, negative permittivity, negative permeability, and negative refractive are achieved. As a result, the proposed unit cell can improve microwave devices’ performance for C, X, and Ku bands, particularly satellite and radar communications.

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基于互补分割方环谐振器的双负超材料在C、X、Ku波段卫星应用

本研究提出了一种基于互联耦合分裂方环谐振器(SSRR)的超材料(MTM)单元电池。双负(DNG)超材料特性在C、X和Ku微波频段表现出来。所提出的MTM单元电池包含六个分裂方环谐振器(SSRR)，其中水平金属棒在第四个和第五个SSRR之间互连，垂直金属棒在第三个和第五个SSRR之间互连。在谐振器和介电层中采用了完美的电导体(PEC)和Rogers- RT 5880来设计MTM单元电池。单元胞的尺寸为10×10×1.57 mm3，谐振层和介电层的厚度分别为0.04 mm和1.57 mm。采用计算机仿真技术(CST Microwave Studio 2019)软件提取有效参数，然后采用有限元法(FEM)验证单元电池的性能。由于结构对称，可实现负介电常数、负磁导率和负折射率。因此，所提出的单元电池可以提高微波器件在C、X和Ku波段的性能，特别是卫星和雷达通信。

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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2021 7th International Conference on Space Science and Communication (IconSpace)

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