Equivalent circuit of a planar microwave liquid sensor based on metamaterial complementary split ring resonator

IF 0.8 4区工程技术 Q4 ENGINEERING, ELECTRICAL & ELECTRONIC Frequenz Pub Date : 2023-10-16 DOI:10.1515/freq-2023-0111

Samira Mekki, Rami Zegadi, Said Mosbah, Djamel Sayad, Issa Elfergani, Mohamed Lamine Bouknia, Jonathan Rodriguez, Arpan Desai, Merih Palandoken, Chemseddine Zebiri

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Abstract

Abstract In the present work, a study of a metamaterial complementary split ring resonator (CSRR) microwave planar sensor for dielectric liquid characterization is carried out using HFSS software. The design consists in a CSRR-loaded two ports rectangular patch microstrip-fed grounded planar structure. The investigated liquid sample is put in a capillary glass tube lying parallel to the surface of the sensor. The liquid test tube is deposited horizontally parallel to the surface of the planar sensor. The advantage of the design lies on the fact that it allows different orientations and multiple size possibilities of the test tube. This makes it possible to explore different resonant frequencies in the 2.1 GHz frequency band. Moreover, an optimization study is carried out to achieve a high sensitivity and a high-quality factor of the proposed sensor. To better understand the operation and to further verify the feasibility of the equivalent circuit, a parallel RLC resonant circuit is used to obtain the desired Z parameter responses Z 11 , Z 22 , Z 21 . A T-shaped electrical model of the proposed sensing structure is established using Advanced Design System (ADS) software. This latter constitutes one of the principal novelties of this work, which has never been addressed so far.

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基于超材料互补裂环谐振器的平面微波液体传感器等效电路

摘要本文利用HFSS软件对介质液体表征的超材料互补裂环谐振器(CSRR)微波平面传感器进行了研究。本设计采用双端口矩形贴片微带馈电接地平面结构。将所研究的液体样品放入与传感器表面平行的毛细管玻璃管中。液体试管水平平行于平面传感器表面沉积。这种设计的优点在于它允许试管的不同方向和多种尺寸的可能性。这使得在2.1 GHz频段探索不同的谐振频率成为可能。此外，还进行了优化研究，使所提出的传感器具有高灵敏度和高质量因子。为了更好地理解其工作原理，并进一步验证等效电路的可行性，采用并联RLC谐振电路获得所需的Z参数响应z11, z22, z21。利用先进设计系统(ADS)软件建立了该传感结构的t型电模型。后者构成了这项工作的主要新奇之处之一，迄今为止从未解决过。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Frequenz 工程技术-工程：电子与电气

CiteScore

2.40

自引率

18.20%

发文量

审稿时长

3 months

期刊介绍： Frequenz is one of the leading scientific and technological journals covering all aspects of RF-, Microwave-, and THz-Engineering. It is a peer-reviewed, bi-monthly published journal. Frequenz was first published in 1947 with a circulation of 7000 copies, focusing on telecommunications. Today, the major objective of Frequenz is to highlight current research activities and development efforts in RF-, Microwave-, and THz-Engineering throughout a wide frequency spectrum ranging from radio via microwave up to THz frequencies. RF-, Microwave-, and THz-Engineering is a very active area of Research & Development as well as of Applications in a wide variety of fields. It has been the key to enabling technologies responsible for phenomenal growth of satellite broadcasting, wireless communications, satellite and terrestrial mobile communications and navigation, high-speed THz communication systems. It will open up new technologies in communications, radar, remote sensing and imaging, in identification and localization as well as in sensors, e.g. for wireless industrial process and environmental monitoring as well as for biomedical sensing.