Design and analysis of SRR based metamaterial loaded circular patch multiband antenna for satellite applications

IF 4.1 3区计算机科学 Q1 COMPUTER SCIENCE, INFORMATION SYSTEMS

ICT Express Pub Date : 2024-08-01 DOI:10.1016/j.icte.2024.05.002

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引用次数: 0

Abstract

Satellite communication has reached a turning point in transmitting data quickly and receiving signals clearly in faraway places. This paper presents a metamaterial-based antenna for distant and military applications that overcomes restrictions and performs unmatched. This project explores metamaterials to create a unique antenna. Expect to be astounded by its power to bend electromagnetic waves, miniaturize, and change our relationship with the universe. The feeding mechanism of this antenna is a modified co-planar waveguide. At 5.6 GHz, the proposed antenna unit cell measures 0.076 $λ_{0}$ $\times 0.2 λ_{0}$ , making it small thanks to its MTM characteristic. CP radiation is made when two orthogonally polarized modes are stimulated at the same time and two composite right- and left-handed transmission line unit cells are placed orthogonally. Reduced size, increased bandwidth, and improved Learn how this discovery opens new doors for high-resolution photography, broadband internet, and space exploration. One nanostructure that makes up a metamaterial is the Split Ring Resonator (SRR). SRR dimensions must be smaller than the resonance wavelength, making them crucial for near-infrared and optical responses. This effort examined nanoscale SRR characteristics in the infrared and visible ranges. SRRs composed of aluminum (Al) and gold (Au) were produced on silicon and silica substrates using electron beam lithography (EBL). The proposed structure consists of a microstrip-line-supplied SRR, a parasitic patch that is perpendicular to the ground plane, and two via holes connected by two split rings that feed the patch indirectly. Choosing the right material parameter for all such antennas depends on the planned structure. Fabrication and testing of the antenna matched simulations. Dimensions: 23.7 mm × 16.2 mm × 1.6 mm; substrate dielectric constant: 4.4. Experimental data are detailed and compared to analytical calculations. Simulation results show that metamaterials have negative permittivity and permeability in a certain frequency range, which can be predicted by an analytical method. Simulations indicated eight BRS, WiMAX, radar, and mobile phone resonance frequencies. Radiation is dipole-like in the omnidirectional in the H-plane and E-plane. 10 dB return loss and 3 dB axial ratio bandwidths are 38.6.7% and 8.1%, respectively.

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卫星应用中基于 SRR 的超材料加载圆形贴片多频带天线的设计与分析

卫星通信已成为在遥远地方快速传输数据和清晰接收信号的转折点。本文介绍了一种用于远距离和军事应用的超材料天线，它克服了各种限制，性能无与伦比。该项目利用超材料创造了一种独特的天线。它能够弯曲电磁波，实现微型化，并改变我们与宇宙的关系。该天线的馈电机制是一个改进的共面波导。在 5.6 千兆赫频率下，拟议的天线单元尺寸为 0.076λ0×0.2λ0，因其 MTM 特性而变得很小。当两个正交极化模式同时受到激励，两个复合的左右手传输线单元正交放置时，就会产生 CP 辐射。缩小尺寸、增加带宽和改进了解这一发现如何为高分辨率摄影、宽带互联网和太空探索打开新的大门。构成超材料的一种纳米结构是裂环谐振器（SRR）。SRR 的尺寸必须小于谐振波长，因此对近红外和光学响应至关重要。这项研究考察了纳米级 SRR 在红外线和可见光范围内的特性。利用电子束光刻技术（EBL）在硅和二氧化硅基底上制作了由铝（Al）和金（Au）组成的 SRR。所提出的结构包括一个由微带线供电的 SRR、一个垂直于地平面的寄生贴片以及由两个分环连接的两个通孔，这两个通孔间接为贴片供电。为所有此类天线选择正确的材料参数取决于规划的结构。天线的制造和测试与模拟相匹配。尺寸23.7 毫米 × 16.2 毫米 × 1.6 毫米；基底介电常数：4.4。详细介绍了实验数据，并与分析计算结果进行了比较。仿真结果表明，超材料在一定频率范围内具有负介电常数和负磁导率，这可以通过分析方法预测。仿真显示了八个 BRS、WiMAX、雷达和手机共振频率。辐射在 H 平面和 E 平面上呈全向偶极子状。10 dB 回波损耗和 3 dB 轴向比带宽分别为 38.6.7% 和 8.1%。

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来源期刊

ICT Express Multiple-

CiteScore

10.20

自引率

1.90%

发文量

167

审稿时长

35 weeks

期刊介绍： The ICT Express journal published by the Korean Institute of Communications and Information Sciences (KICS) is an international, peer-reviewed research publication covering all aspects of information and communication technology. The journal aims to publish research that helps advance the theoretical and practical understanding of ICT convergence, platform technologies, communication networks, and device technologies. The technology advancement in information and communication technology (ICT) sector enables portable devices to be always connected while supporting high data rate, resulting in the recent popularity of smartphones that have a considerable impact in economic and social development.