A wideband, thin profile and enhanced gain microstrip patch antenna modified by novel mushroom-like EBG and periodic defected ground structures

IF 1.2 4区工程技术 Q4 ENGINEERING, ELECTRICAL & ELECTRONIC

Journal of Electromagnetic Waves and Applications Pub Date : 2023-10-23 DOI:10.1080/09205071.2023.2270603

Cemile Tangel, Nigar Berna Teşneli

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引用次数: 0

Abstract

AbstractThis paper presents a wideband, thin-profile and enhanced-gain microstrip patch antenna improved by using a novel mushroom-like Electromagnetic Band Gap (EBG) structure and forming periodic Defected Ground Structures (DGS) on the ground plane. The proposed antenna operates between 9.56 and 14 GHz and has 4.44 GHz–10 dB impedance bandwidth. With A4, the gain of the reference antenna is increased by 64.4%, while a 38% bandwidth is also achieved. The parametric analyses carried out on the metallic part area of the novel EBG patch indicated that when the area of the used EBG patches are approximately three quarters or less of the conventional ones, greater gain values for the designed antenna are obtained. This relation between the EBG patches and the antenna gain can be pointed out as the novelty of the study. The results were analysed by the simulations carried out with CST Microwave Studio and were verified by measurements from manufactured prototypes.KEYWORDS: Widebandthin-profilegain enhancementmicrostrip antennaEBGDGS Disclosure statementNo potential conflict of interest was reported by the author(s).Additional informationNotes on contributorsCemile TangelCemile Tangel received BSc degree from Gazi University, Dept. of Electrical and Electronics Eng. in 1991, and MSc degree from Kocaeli University Dept. of Electronics and Comimunication Eng. in 2009. She has currently been pursuing PhD degree in Electrical and Electronics Engineering, Graduate Education Institute, Sakarya University of Applied Sciences, Sakarya, Turkey. Her research areas include electromagnetic theory, antenna designs, microstrip antennas and EBG structures.Nigar Berna TeşneliNigar Berna Teşneli received the B.S., M.S., and Ph.D. degrees in Physics Engineering from the Faculty of Engineering, University of Hacettepe, Ankara, Turkey, in 1998, 2000, and 2005, respectively. She worked at the Department of Physics Engineering, University of Hacettepe, Ankara, Turkey and with the Department of Electrical and Electronics Engineering, University of Sakarya, Sakarya, Turkey. She has been with the Nanomaterial Engineering Group, University of Sheffield, Sheffield, U.K., as visiting researcher in 2003. Since 2018, she has been working as an Assistant Professor with the Department of Engineering Fundamental Sciences, Sakarya University of Applied Sciences, Sakarya, Turkey. Her research interests include electromagnetic field theory, antenna design, metamaterials, electromagnetic bandgap structures, frequency selective surfaces, electromagnetic measurements and electromagnetic compatibility.

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一种由新型蘑菇状EBG和周期性缺陷地面结构改进的宽带、薄轮廓和增强增益微带贴片天线

摘要本文提出了一种利用新型蘑菇状电磁带隙(EBG)结构和在地平面上形成周期性缺陷接地结构(DGS)改进的宽带、薄型和增强增益微带贴片天线。所提出的天线工作在9.56和14 GHz之间，具有4.44 GHz - 10 dB阻抗带宽。采用A4时，参考天线的增益提高了64.4%，同时带宽也提高了38%。对新型EBG贴片的金属部分面积进行了参数化分析，结果表明，当所采用的EBG贴片面积约为传统贴片面积的四分之三或更小时，所设计天线的增益值更高。电子电信号贴片与天线增益之间的关系是本研究的新颖之处。通过CST微波工作室进行的模拟分析了结果，并通过制造原型的测量进行了验证。关键词:宽带薄剖面增强微带天线ebgdgs披露声明作者未报告潜在利益冲突。作者简介:semile Tangel获得Gazi大学电气与电子工程系学士学位。1991年毕业于高丽大学电子与通信工程系，获硕士学位。在2009年。她目前正在攻读电气和电子工程博士学位，研究生教育研究所，萨卡里亚应用科学大学，萨卡里亚，土耳其。她的研究领域包括电磁理论、天线设计、微带天线和EBG结构。Nigar Berna te，分别于1998年、2000年和2005年获得土耳其安卡拉Hacettepe大学工程学院物理工程学士学位、硕士学位和博士学位。她曾在土耳其安卡拉的Hacettepe大学物理工程系和土耳其萨卡里亚大学电气与电子工程系工作。她于2003年在英国谢菲尔德大学纳米材料工程小组担任访问研究员。自2018年以来，她一直在土耳其萨卡里亚应用科学大学工程基础科学系担任助理教授。她的研究兴趣包括电磁场理论、天线设计、超材料、电磁带隙结构、频率选择表面、电磁测量和电磁兼容性。

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来源期刊

Journal of Electromagnetic Waves and Applications 物理-工程：电子与电气

CiteScore

3.60

自引率

7.70%

发文量

116

审稿时长

3.3 months

期刊介绍： Journal of Electromagnetic Waves and Applications covers all aspects of electromagnetic wave theory and its applications. It publishes original papers and review articles on new theories, methodologies, and computational techniques, as well as interpretations of both theoretical and experimental results. The scope of this Journal remains broad and includes the following topics: wave propagation theory propagation in random media waves in composites and amorphous materials optical and millimeter wave techniques fiber/waveguide optics optical sensing sub-micron structures nano-optics and sub-wavelength effects photonics and plasmonics atmospherics and ionospheric effects on wave propagation geophysical subsurface probing remote sensing inverse scattering antenna theory and applications fields and network theory transients radar measurements and applications active experiments using space vehicles electromagnetic compatibility and interferometry medical applications and biological effects ferrite devices high power devices and systems numerical methods The aim of this Journal is to report recent advancements and modern developments in the electromagnetic science and new exciting applications covering the aforementioned fields.