S和C波段应用的角度无关超材料吸收体

Q3 Materials Science Progress in Electromagnetics Research C Pub Date : 2023-07-06 DOI:10.2528/pierc22120501
Goriparthi Rajyalakshmi, Y. Ravikumar, D. Ramakrishna, Samba Siva Rao Kumbha
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引用次数: 0

摘要

本文介绍了不依赖于角度的超材料微波吸收器的发展和设计。单晶胞由两个同心圆组成,它们由整合电阻连接。吸收器建立在厚度为3.2 mm (λ/0.07),介电常数为4.3的介电衬底(FR4)上。在2.8 ~ 10.42 GHz范围内获得宽带吸收,其中7.62 GHz宽带吸收率在90%以上。在感兴趣的区域,得到了一个平坦的波段,为了检查各自区域的电流分布和电场,考虑了两个峰,频率为3.66和9.54 GHz,最大吸光度分别为99.99%和99.44%。在不同角度下对所提出的吸收器进行了phi和θ变化的检验。从phi的变化,可以观察到,对于所有的角度,吸收率都不变化,这证实了吸收器的作用与角度无关。制造的薄片由一个单元阵列组成,在两个喇叭天线和矢量网络分析仪的帮助下在消声室内进行检测。将试验结果与模拟结果进行了比较,发现两者吻合较好。在本文的最后,对所提出的和已经报道的艺术进行了比较,并观察到所提出的艺术在低频下具有较高的带宽。所提出的吸波器可实际用于减少雷达横截面的防御应用。
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Angle Independent Metamaterial Absorber for S and C Band Application
In this paper, the development and designing of angle-independent metamaterial microwave absorbers are presented. The unit cell consists of two concentric circle that are linked by consolidated resistors. The absorber is built on a dielectric substrate (FR4) with a thickness of 3.2 mm (λ/0.07) and a dielectric constant of 4.3. The wideband absorption is acquired in the range of 2.8 to 10.42 GHz with a wide band of 7.62 GHz with absorptivity above 90%. In the area of interest, a flat band is obtained, and to examine the current distribution and electric field in the respective region, two peaks are considered at a frequency of 3.66 and 9.54 GHz, with maximum absorptivity of 99.99% and 99.44%, respectively. The presented absorber is examined under different angles for phi and theta variation. From the phi variation, it is observed that for all the angles, absorptivity does not vary, which confirms that the absorber is acting as an angle independent. The fabricated sheet consists of an array of a unit cell, which is examined inside the anechoic chamber with the help of two horn antennas and vector network analyzer. The tested and simulated results are compared, and it was observed that they are close in their agreement. At the end of the manuscript, the presented and already reported arts are compared, and it is observed that the presented one operates for the low frequency with higher bandwidth. The presented absorber can be practically used for defense applications for Radar Cross Sections reduction.
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来源期刊
Progress in Electromagnetics Research C
Progress in Electromagnetics Research C Materials Science-Electronic, Optical and Magnetic Materials
CiteScore
2.70
自引率
0.00%
发文量
113
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