Design, Simulation, and Construction of a SWB Antenna Using a Metasurface Luneburg LENS

IF 1.5 4区 工程技术 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC
Vahid Reza Bagheri, Alireza Yahaghi, Habibollah Abiri
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Abstract

In this work, a novel compact antenna with a super-wideband (SWB) feeding (3–43 GHz) is designed. The SWB lens antenna consists of a super-wideband feeding, a parallel plate waveguide (PPW), and a dielectric lens. The flat Luneburg lens has been designed and implemented based on metasurface technology. This antenna can be employed as a sense antenna in ultrawideband (UWB) applications. Attaining a SWB antenna that also grants a high gain in the whole bandwidth is a major issue considered in this work. The introduced structure reveals a very good matching properties (VSWR < 2.15) and also acceptable gain (5–13.5dBi) and very good efficiency (typ. > 83%) in the whole ultrawide bandwidth (3–43GHz). Another important feature of the proposed structure is its capability for being used in multi-beam applications by merely adding some extra feeding ports to it. To show this, the designed lens is fed by three ports placed on its circumference with 30° angular separation. These results show three beam directions in − 30°, + 30°, and 0°, and in addition to its broad bandwidth, excellent impedance matching and close-to-ideal port isolation are achieved.

Abstract Image

使用超表面Luneburg透镜的SWB天线的设计、仿真和构造
在这项工作中,设计了一种具有超宽带馈电(3-43 GHz)的新型紧凑型天线。SWB透镜天线由超宽带馈电、平行板波导(PPW)和介质透镜组成。基于超表面技术设计并实现了平面吕尼堡透镜。该天线可作为超宽带(UWB)应用中的传感天线。在整个带宽中获得高增益的SWB天线是本工作中考虑的主要问题。该结构在整个超宽带(3-43GHz)范围内具有良好的匹配性能(VSWR 2.15)、可接受的增益(5-13.5dBi)和良好的效率(83%)。所提出的结构的另一个重要特征是它的能力,可用于多波束应用,只需增加一些额外的馈电端口到它。为了证明这一点,设计的透镜是由三个端口放置在其圆周上与30°角分离。这些结果表明,在−30°,+ 30°和0°三个波束方向上,除了宽带宽外,还实现了出色的阻抗匹配和接近理想的端口隔离。
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来源期刊
CiteScore
5.50
自引率
4.20%
发文量
93
审稿时长
>12 weeks
期刊介绍: Transactions of Electrical Engineering is to foster the growth of scientific research in all branches of electrical engineering and its related grounds and to provide a medium by means of which the fruits of these researches may be brought to the attentionof the world’s scientific communities. The journal has the focus on the frontier topics in the theoretical, mathematical, numerical, experimental and scientific developments in electrical engineering as well as applications of established techniques to new domains in various electical engineering disciplines such as: Bio electric, Bio mechanics, Bio instrument, Microwaves, Wave Propagation, Communication Theory, Channel Estimation, radar & sonar system, Signal Processing, image processing, Artificial Neural Networks, Data Mining and Machine Learning, Fuzzy Logic and Systems, Fuzzy Control, Optimal & Robust ControlNavigation & Estimation Theory, Power Electronics & Drives, Power Generation & Management The editors will welcome papers from all professors and researchers from universities, research centers, organizations, companies and industries from all over the world in the hope that this will advance the scientific standards of the journal and provide a channel of communication between Iranian Scholars and their colleague in other parts of the world.
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