A Low-Profile Antenna Based on Single-Layer Metasurface for Ku-Band Applications

Abdulkarim, Yadgar I.; Awl, Halgurd N.; Muhammadsharif, Fahmi F.; Karaaslan, Muharrem; Mahmud, Rashad H.; Hasan, Sattar Othman; Isik, Omer; Luo, Hang; Huang, Shengxiang

doi:10.1155/2020/8813951

Cited by 23 publications

(11 citation statements)

References 32 publications

(28 reference statements)

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“…Metamaterials (MTMs) are artificial structures that exhibit exotic properties of negative permittivity, negative permeability, and a negative refractive index in the frequency range of interest [1]. Metamaterials can be used for various applications such as sensing [2,3], super lensing [4,5], cloaking [6,7], imaging [8], antennae [9], and wave absorption [10]. Studies on micro-and nano-sized designs in high frequency bands have been paired with technological developments; this is specifically important for the development of high chemical selectivity and the penetration of opaque materials.…”

Section: Introductionmentioning

confidence: 99%

A Symmetrical Terahertz Triple-Band Metamaterial Absorber Using a Four-Capacitance Loaded Complementary Circular Split Ring Resonator and an Ultra-Thin ZnSe Substrate

et al. 2022

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In this research work, a symmetrical four-capacitance loaded complementary circular split ring resonator is proposed, which uses an ultra-thin Zinc Selenide (ZnSe) substrate to realize a low-profile triple-band metamaterial (MTM) perfect absorber for application in the terahertz (THz) frequency range. The electromagnetic properties of the proposed structure were calculated and investigated using the Finite Integration Technique (FIT). The proposed structure exhibited three highly absorptive (nearly perfect) peaks at the resonance frequencies of 15.68 THz, 37.48 THz, and 39.55 THz. Furthermore, the absorber was found to be insensitive to the polarization and incident wave angles, due to its symmetrical design. The effects of the conductor type, substrate thickness, unit cell dimension, resonator gap, and substrate type on the reflection and absorption spectra were investigated. To validate the numerical results, the proposed design was analyzed using High-Frequency Simulation Software (HFSS) and Advanced Design System (ADS). The surface current, electric field, and magnetic field distributions at the three-resonance frequency were analyzed. It was concluded that the overall performance of the proposed MTM structure was superior compared to those reported in the literature. The proposed design could be a good candidate for application in stealth technology, imaging, and thermal energy harvesting.

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Section: Introductionmentioning

confidence: 99%

A Symmetrical Terahertz Triple-Band Metamaterial Absorber Using a Four-Capacitance Loaded Complementary Circular Split Ring Resonator and an Ultra-Thin ZnSe Substrate

et al. 2022

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“…A compact low-cost PRS having a non-uniform double-sided printed single-layer dielectric slab was proposed in [ 13 ]. Similarly, different shapes of unit cell patch designs were studied in [ 14 , 15 , 16 , 17 , 18 , 19 ], where the use of electrically thin substrates with the respective designed patches was shown. This further shows the design complexity with a complex geometry, which results in an increased fabrication cost.…”

Section: Introductionmentioning

confidence: 99%

Miniaturized Wideband Antenna Prototype Operating over the Ku-Band

et al. 2022

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A wideband antenna is proposed based on three-dimensional printing technology. The antenna was designed using the PREPERM 10 material, with permittivity ϵr = 10, where the overall height of the proposed prototype was maintained as 12.83 mm (0.51λ), having a lateral dimension of 60 mm × 60 mm, at an operating frequency of 12 GHz (λ = 25 mm). The proposed antenna achieved a wide frequency bandwidth with a voltage standing-wave ratio (VSWR) of less than two, from 10 GHz to 15 GHz in the Ku-band, where the maximum directivity was 20 dBi over a reflection coefficient bandwidth of 50%. It showed a miniaturized non-uniform metasurface of 2.4λ× 2.4λ× 0.51λ that was placed at 16.5 mm (0.66λ) above the ground plane, which was 2.4λ× 2.4λ× 0.04λ in dimension. Thus, the overall height of the proposed antenna system from the feed source was 29.33 mm (1.17λ). The total weight of the system including the designed structures made of PREPERM 10 and ABS with copper-painted prototypes was 96 g and 79 g, respectively. The measured results were consistent with the simulated results, demonstrating the feasibility and effectiveness of the proposed method.

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“…It is noteworthy to highlight that the NGD solution enables preservation of the signal quality without affecting the information speed. The NGD function was innovatively implemented within microwave circuits [15] as antenna [16,17] and sensor [18][19][20] performances by using negative refractive index resonant metamaterials, antenna beamformer [21,22], non-Foster network designing [23], and independent frequency NGD phase shifter [24]. Analytical modeling of transmission line (TL) and electrical interconnects were developed [25].…”

Section: Introductionmentioning

confidence: 99%

Design and Modelling of Ladder-Shape Topology Generating Bandpass NGD Function

Ngoho¹,

Boussougou²,

Yazdani³

et al. 2021

PIER C

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This paper introduces a model and design of an innovative bandpass (BP) negative group delay (NGD) distributed circuit. The passive circuit topology under study is constituted by fully distributed elements without lumped components. The NGD passive structure is implemented as a ladder shape topology composed of distributed transmission line (TL) elements. The S-matrix model is established from TL-based equivalent Z-matrix operations with respect to the ladder geometry. As a proof of concept, a two-cell ladder prototype is designed in microstrip technology, which is simulated, fabricated, and tested. The calculated and simulated measurements are in very good agreement with the validation of BP NGD behaviour. NGD value is better than −3 ns with centre frequency between 3.56 and 3.68 GHz over more than 30 MHz NGD bandwidth being observed. The circuit operates under insertion loss better than 5 dB and reflection loss better than 8 dB. This innovative BP NGD passive circuit can be useful in the RF and microwave engineering area, for example, to reduce the signal propagation delay in the upcoming and 5G telecommunication systems.

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A Low-Profile Antenna Based on Single-Layer Metasurface for Ku-Band Applications

Cited by 23 publications

References 32 publications

A Symmetrical Terahertz Triple-Band Metamaterial Absorber Using a Four-Capacitance Loaded Complementary Circular Split Ring Resonator and an Ultra-Thin ZnSe Substrate

A Symmetrical Terahertz Triple-Band Metamaterial Absorber Using a Four-Capacitance Loaded Complementary Circular Split Ring Resonator and an Ultra-Thin ZnSe Substrate

Miniaturized Wideband Antenna Prototype Operating over the Ku-Band

Design and Modelling of Ladder-Shape Topology Generating Bandpass NGD Function

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