Design of a Compact Passband Frequency Selective Surface with Stable Resonance

Peddakrishna, Samineni; Khan, Taimoor; Kanaujia, Binod Kumar; Nasimuddin, Nasimuddin

doi:10.1155/2017/7696039

Cited by 9 publications

(3 citation statements)

References 14 publications

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“…In References 19, 20, authors have used multilayer FSSs to generate a multi‐stop‐band structure with a wide band property to enhance the gain but at the same time it increases both design profile and complexity. A convoluted circular FSS unit cell, alongside an interwoven with a convoluted element from a simple spiral dipole array, have been proposed by authors of References 21, 22 to achieve the desired miniaturization and frequency stability 23,24 aspects of an FSS array. In Reference 15, the authors proposed a novel and an attractive cylindrical antenna for microwave radiology imaging (MRI) applications, where an in‐phase FSS‐based reflector is introduced to the main UWB antenna, to enhance both the bandwidth and the front to back ratio, resulting in a well‐performing antenna, operating over a wide bandwidth ranging from 7.8 to 15 GHz, and a bore‐sight gain varying from 2 dBi up to 6 dBi.…”

Section: Introductionmentioning

confidence: 99%

Performance enhancement of an ultra‐wideband antenna using a compact topology optimized single frequency selective surface‐layer as a reflector

Melouki

Hocini

Denidni

2022

Int J RF Mic Comp-Aid Eng

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In this article, an ultra‐wideband (UWB) topology optimized frequency selective surface (FSS) is introduced as a reflecting layer, to maximize the gain and overall performances of an UWB monopole antenna. The single Rogers RO4350B‐based FSS layer is synthesized using an automated system, based on an interface bridged between CST Microwave studio and Matlab, and optimized using a binary genetic algorithm. First, the FSS unit cell foot print needs to be as small as possible, while covering a wider frequency range, and to achieve these performances, the proposed genetic algorithm synthesizing system achieved an FSS unit cell with only 0.1 λ × 0.1 λ at the lower‐end frequency, covering a bandwidth of 2.9–14.5 GHz. Polarization independence is achieved also, due to the four‐folded symmetry imposed on the FSS unit cell. The proposed antenna is designed on a Rogers RO4350B substrate, and backed at a distance of 18.74 mm by an FSS structure. The fabricated prototype shows a bandwidth of 3.1–13.9 GHz, and an excellent maximum peak gain of 9.7 dBi, with an improvement of 3.41 dBi cross the UWB spectrum (from 3.7 to 7.11 dBi), and in good agreement with the simulation results, which made the proposed design a promising candidate for UWB applications requiring high gain, such as ground‐penetrating radar, and microwave radiology imaging (MRI) systems.

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Section: Introductionmentioning

confidence: 99%

Performance enhancement of an ultra‐wideband antenna using a compact topology optimized single frequency selective surface‐layer as a reflector

Melouki

Hocini

Denidni

2022

Int J RF Mic Comp-Aid Eng

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“…Miniaturized FSS can be used to overcome the above difficulties. Many methods are employed to achieve the purpose of unit size reduction, including the coupling technology based on the capacitive surface and inductive surface [13][14][15], loading with passive lumped elements (capacitors and inductors) [16,17], and the unit curling and interdigitating design [18][19][20][21][22][23]. In [18], a convoluted structure is used for miniaturized FSS, and the element size is about 0.08 wavelength of the free-space.…”

Section: Introductionmentioning

confidence: 99%

“…In [18], a convoluted structure is used for miniaturized FSS, and the element size is about 0.08 wavelength of the free-space. In [19], a miniaturized FSS is single layer and composed of the Archimedean spiral type with the interdigital capacitance between the corners of metallic patches, and the element size is about 0.066 wavelength at the resonant frequency. In [20], a miniaturized dual-band FSS with closely spaced resonance is proposed.…”

Section: Introductionmentioning

confidence: 99%

Design of Miniaturized and Polarization-Insensitive Double-Layer Frequency Selective Surface Based on Meander Lines

Huo

Liu

Zhu

et al. 2021

International Journal of Antennas and Propagation

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The work presented in this paper concerns a method for the miniaturized frequency selective surface (FSS) based on the meander lines. A miniaturized dual-bandstop FSS structure based on meander lines with spiral-shape is proposed and simulated. The equivalent circuit and current distributions are introduced to explain the FSS performance. The size of the unit cell is 10 mm, which is about 0.037 wavelength at the first resonant frequency. Simulation results indicate that the proposed FSS has a frequency shift smaller than 1% for different polarizations with an oblique incident angle of 60°. A prototype of the FSS is fabricated and measured. The measurement results show that the FSS is polarization-insensitive and angle-insensitive.

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