Design of a Circularly-Polarized Microstrip Antenna by Utilizing Mutually-Coupled Resonators

IF 3.5 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC IEEE Open Journal of Antennas and Propagation Pub Date : 2024-09-04 DOI:10.1109/OJAP.2024.3454330
Jia-Xiang Hao;Hui-Dong Li;Lei Zhu
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Abstract

This article proposes a design method for a circularly-polarized (CP) antenna, which is realized by using coupling effects. Initially, the desired electric(magnetic) coupling between two identical $\lambda$ /4 short-circuited microstrip line (MS-L) resonators can be generated when the short-circuited (opencircuited) ends of the resonators are in close proximity to each other. Besides, an orthogonal arrangement in space for these two resonators has been adopted to yield two orthogonal linearly-polarized (LP) waves. Therefore, a desired CP rotation can be achieved by choosing corresponding coupling types. Meanwhile, two equivalent circuit models are established and analyzed to deduce the formulas of the mutual inductance and mutual capacitance for the desired CP radiation. Afterwards, a binary array consisting of a magnetically coupled (MC) pair of resonators and an electrically coupled (EC) pair of resonators is proposed for expanding the axial ratio bandwidth (ARBW) and enhancing peak gain. Finally, a right-handed circularlypolarized (RHCP) antenna with magnetic coupling, a left-handed circularly-polarized (LHCP) antenna with electric coupling and a binary array are fabricated and tested. And an excellent agreement is validated between the experiment and simulation results. The measured results show that the binary array achieves a maximum gain of 5 dBic within its measured ARBW range of 3.535 – 3.615 GHz. In contrast, the single pairs (EC or MC pair) exhibit a gain of 3 dBic. Additionally, the array demonstrates a fivefold expansion in ARBW compared to the single pair.
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利用互耦合谐振器设计圆极化微带天线
本文提出了一种利用耦合效应实现圆极化(CP)天线的设计方法。首先,当两个相同的 $\lambda$ /4 短路微带线(MS-L)谐振器的短路(开路)端相互靠近时,就能在这两个谐振器之间产生所需的电(磁)耦合。此外,这两个谐振器在空间中采用了正交排列,以产生两个正交线性极化(LP)波。因此,通过选择相应的耦合类型,可以实现理想的 CP 旋转。同时,建立并分析了两个等效电路模型,从而推导出所需 CP 辐射的互感和互容公式。随后,提出了一种由一对磁耦合(MC)谐振器和一对电耦合(EC)谐振器组成的二元阵列,用于扩大轴向比带宽(ARBW)和提高峰值增益。最后,制作并测试了磁耦合右旋圆极化(RHCP)天线、电耦合左旋圆极化(LHCP)天线和二元阵列。实验和仿真结果之间的一致性非常好。测量结果表明,二元阵列在 3.535 - 3.615 GHz 的 ARBW 测量范围内实现了 5 dBic 的最大增益。相比之下,单对(EC 或 MC 对)的增益为 3 dBic。此外,该阵列的 ARBW 比单对阵列扩大了五倍。
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来源期刊
CiteScore
6.50
自引率
12.50%
发文量
90
审稿时长
8 weeks
期刊最新文献
Front Cover Table of Contents Guest Editorial Introduction to the Special Section on Women’s Research in Antennas and Propagation Section (WRAPS) IEEE ANTENNAS AND PROPAGATION SOCIETY IEEE Open Journal of Antennas and Propagation Instructions for authors
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