Design of miniaturized ultra-wide stopband lowpass-bandpass diplexer using hexagon-shaped resonators

IF 2.1 4区 计算机科学 Q3 COMPUTER SCIENCE, INFORMATION SYSTEMS Wireless Networks Pub Date : 2024-03-08 DOI:10.1007/s11276-024-03684-7
Ali-Reza Zarghami, Mohsen Hayati, Sepehr Zarghami
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Abstract

This paper presents a lowpass-bandpass diplexer with ultra-wide stopband and low insertion loss using hexagon-shaped resonators. The proposed diplexer consists of a bandpass (BPF) and a lowpass filter (LPF), representing the core concept of the proposed design method that aims to concurrently design BPF and LPF. In this proposed design method, the influence of the LPF filter on the BPF's design has been identified through coupling matrix analysis for the first time. Initially, an LPF is designed based on three coupled hexagon-shaped elliptical resonators. Subsequently, a novel model for BPF design, utilizing coupled high-impedance lines, has been introduced. Following this, the BPF model is developed using coupling matrix analysis while considering the impact of LPF resonators. The LPF have a 1.32 GHz cut-off frequency and ultra-wide stopband up to 17.42 GHz. The BPF consisted of four resonators and the hexagon-shaped structure is used instead of low impedance lines. The utilization of hexagon-shaped resonators serves the purpose of enhancing the precision of the coupling effect, aligning with the proposed coupling matrix analysis. Additionally, hexagon-shaped resonators exhibit a greater capacitive effect, leading to a reduction in insertion loss within the passband when compared to rectangular-shaped resonators. The BPF has narrow passband with center frequency of is 2.25 GHz and 0.31 GHz bandwidth. The measured insertion losses of LPF and BPF are < 0.75 dB and 0.81 dB, respectively in 60% of passbands.

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利用六角形谐振器设计微型超宽截止带低通-带通双工器
本文利用六角形谐振器提出了一种具有超宽截止带和低插入损耗的低通带通双工器。所提出的双工器由一个带通(BPF)和一个低通滤波器(LPF)组成,代表了所提出的设计方法的核心理念,即同时设计 BPF 和 LPF。在这种设计方法中,首次通过耦合矩阵分析确定了 LPF 滤波器对 BPF 设计的影响。首先,基于三个耦合六角形椭圆谐振器设计 LPF。随后,引入了一种利用耦合高阻抗线的新型 BPF 设计模型。随后,在考虑 LPF 谐振器影响的同时,利用耦合矩阵分析开发了 BPF 模型。LPF 具有 1.32 GHz 的截止频率和高达 17.42 GHz 的超宽阻带。BPF 由四个谐振器组成,采用六角形结构代替低阻抗线。使用六角形谐振器的目的是提高耦合效应的精度,这与提出的耦合矩阵分析相一致。此外,与矩形谐振器相比,六角形谐振器表现出更大的电容效应,从而降低了通带内的插入损耗。BPF 具有中心频率为 2.25 GHz、带宽为 0.31 GHz 的窄通带。在 60% 的通带内,LPF 和 BPF 的测量插入损耗分别为 0.75 dB 和 0.81 dB。
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来源期刊
Wireless Networks
Wireless Networks 工程技术-电信学
CiteScore
7.70
自引率
3.30%
发文量
314
审稿时长
5.5 months
期刊介绍: The wireless communication revolution is bringing fundamental changes to data networking, telecommunication, and is making integrated networks a reality. By freeing the user from the cord, personal communications networks, wireless LAN''s, mobile radio networks and cellular systems, harbor the promise of fully distributed mobile computing and communications, any time, anywhere. Focusing on the networking and user aspects of the field, Wireless Networks provides a global forum for archival value contributions documenting these fast growing areas of interest. The journal publishes refereed articles dealing with research, experience and management issues of wireless networks. Its aim is to allow the reader to benefit from experience, problems and solutions described.
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