A Circular Split Ringe Resonator (CSRR) Left Handed Metamaterial (LHM) having Simultaneous Negative Permeability and Permittivity

Hindy, Moataza; El-Sagheer, Ragab M.; Yasseen, M. S.

doi:10.14257/ijhit.2017.10.1.15

Cited by 3 publications

(2 citation statements)

References 15 publications

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“…Parameters of mu negative metamaterial cell are extracted using MATLAB script to obtain the curve of complex permeability. Different types of metamaterials are there and they are used for various applications [9][10][11]. Using this modeled cell Rectangular microstrip patch antenna (RMPA) has been designed.…”

Section: Introductionmentioning

confidence: 99%

Microstrip patch antenna design using mathematically modeled metamaterial cell

Satarkar,

Lohani

2023

IOP Conf. Ser.: Mater. Sci. Eng.

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Metamaterial is an artificial material made up of different types of structural designs on a dielectric substrate. In this paper, a broad investigation is being carried out by mathematically modeling and simulating a single negative metamaterial cell comprising a square split ring resonator with two rings. This metamaterial cell has negative permeability values for a particular frequency range. By enhancing properties like bandwidth, reflection loss, and gain in microstrip patch antennae, these metamaterial cells demonstrate unusually remarkable applications in this field. The resonance frequency obtained by simulating the metamaterial cell is compared with the calculated value from the circuit model. The resonance frequency expression is made simple by evaluating the effective permittivity of the substrate after loading the metallic structure on a dielectric substrate. The resonant frequency predicted analytically is found to be extremely close to the frequency obtained by modeling metamaterial structure. A parameter-retrieval method utilising the S parameters is used to determine the curves for the complex permeability of the metamaterial based on its unit element. In order to obtain the S parameters, modeling software is used. This modeled cell is used for designing a rectangular microstrip patch antenna. The parameters such as bandwidth, Gain, return loss, antenna, and metamaterial-based antenna are compared and recorded.

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Section: Introductionmentioning

confidence: 99%

Microstrip patch antenna design using mathematically modeled metamaterial cell

Satarkar,

Lohani

2023

IOP Conf. Ser.: Mater. Sci. Eng.

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“…diatasi menggunakan suatu teknik yang disebut dengan metamaterial. Metamaterial merupakan suatu teknik yang membuat suatu struktur dapat menampilkan nilai permitivitas atau permeabiltasnya seolaholah bernilai negatif (Joshi et al, 2018) (Hindy et al, 2017) (G. et al, 2019). Selain itu, metamaterial juga dapat mengubah aliran arus pada antena sehingga antena memiliki frekuensi resonansi yang baru (Christydass & Gunavathi, 2018).…”

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Complimentary Split Ring Resonators Design On Patch Mikrostrip Antenna For Reducing Ads-B Antenna Dimension

Yusdartono

Bintoro

Badriana

et al. 2022

JITE

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Microstrip Patch Antenna works for Automatic Dependent Surveillance – Broadcast (ADS-B) and antenna frequency resonances at 1.09 GHz. Microstrip Patch Antenna dimension has big shape for antenna micostrip resonancing frequency at 1.09 GHz. In order to Solve this problem, metamaterial is chosen and Complimentary Split Ring Resonators (CSRRs) is the one of metamaterial technique. Complimentary Split Ring Resonators CSRRs is derived from a Split Ring Resonator (SRR) compliment. Early dimension of Microstrip antenna substrate and patch are calculated by Equation that dimension of substrate is 137x130 mm and dimension of patch is 85x65. Dimension of SRR that compliment forms to CSRRs is 9x6 mm for SRR inner ring and 13x10 mm for outer ring. Microstrip antenna VSWR is 1.134 and VSWR increases to 22,73 when CSRR is etched on antenna patch. In order to decrease antenna VSWR, optimation is applied by substrate and patch dimension iteration. Substrate and patch dimension Iteration is enlarge and reduce antenna substrate and patch width and length. Optimation result is VSWR that VSWR comes to 1,559 and substrate and patch dimension is reduced to 27,9% and 14,1%.

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