Equivalent circuit of a planar microwave liquid sensor based on metamaterial complementary split ring resonator-Reference-Cited by-同舟云学术

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

Published:2023-10-16 Issue:1-2 Volume:78 Page:37-45
ISSN:0016-1136
Container-title:Frequenz
language:en
Short-container-title:

Author:

Mekki Samira¹,Zegadi Rami¹^ORCID,Mosbah Said¹,Sayad Djamel²,Elfergani Issa³⁴,Bouknia Mohamed Lamine¹,Rodriguez Jonathan³,Desai Arpan⁵,Palandoken Merih⁶,Zebiri Chemseddine¹^ORCID

Affiliation:

1. Laboratoire d’Electronique de puissance et commande industrielle (LEPCI), Department of Electronics , University of Ferhat Abbas, Sétif-1 , 19000 Sétif , Algeria

2. Laboratoire d’Electrotechnique de Skikda (LES), Department of Electrical Engineering , University 20 Aout 1955-Skikda , Skikda 21000 , Algeria

3. Instituto de Telecomunicações , Campus Universitário de Santiago 3810-193 Aveiro , Portugal

4. Faculty of Engineering and Informatics , University of Bradford , Bradford , UK

5. Department of Electronics and Communication Engineering , CSPIT, Charotar University of Science and Technology (CHARUSAT) , Changa 388421 , India

6. Department of Electrical and Electronics Engineering , Izmir Katip Celebi University , No: 33/2 , Izmir 35620 , Türkiye

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.

Publisher

Walter de Gruyter GmbH

Subject

Electrical and Electronic Engineering

Link

https://www.degruyter.com/document/doi/10.1515/freq-2023-0111/pdf

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