Study on the effect of the substrate material type and thickness on the performance of the filtering antenna design

Alkhafaji, Mohammed K.; Alhamadani, Hana’a A.; Al‐Yasir, Yasir I. A.; Saleh, Ameer L.; Parchin, Naser Ojaroudi; Abd‐Alhameed, Raed A.

doi:10.12928/telkomnika.v18i1.13189

Cited by 12 publications

(8 citation statements)

References 16 publications

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“…This chapter presents the characteristics of proposed microstrip antenna, which includes reflection coefficient S11, VSWR, 2D 3D polar plot gain, 3D polar plot directivity, bandwidth and radiation efficiency [28]. The parameters are clarified in accordance to the results obtained.…”

Section: Resultsmentioning

confidence: 84%

Design of circular-shaped microstrip patch antenna for 5G applications

2022

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Section: Resultsmentioning

confidence: 84%

Design of circular-shaped microstrip patch antenna for 5G applications

2022

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“…2(d)]. The increased signal intensity can be partly ensured by applying dielectric substrates having low ε r since these materials allows the EM waves to propagate through with less attenuation and back reflection compared to dielectrics with higher ε r [10]. In the second measurement setup [Fig.…”

Section: Characterization Of the Fzp Lensmentioning

confidence: 99%

“…Dielectric materials having low relative permittivity (ε r ) and loss factor (tan δ) are particularly important constituents of structural parts of radio frequency devices including antennas, resonators and filters to avoid signal attenuation, unnecessary device heating and propagation delay [4], [5], [6], [7], [8], [9], [10]. Among these components, antennas operating at THz frequencies need to have very high gain due to the increased propagation loss in this range.…”

Section: Introductionmentioning

confidence: 99%

An Ultralow-Loss and Lightweight Cellulose-Coated Silica Foam for Planar Fresnel Zone Plate Lens Applications in Future 6G Devices

Kokkonen

Pálvölgyi

Śliz

et al. 2023

Antennas Wirel. Propag. Lett.

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Several passive components of fifth-generation (5G) and future sixth-generation (6G) telecommunication devices require substrate materials of very low dielectric permittivity and losses to avoid wave absorption, reflection, and interference. Apart from their dielectric properties, these materials shall be also affordable and sufficiently robust to enable postprocessing and integration of functional electrical components. Herein, we demonstrate a Fresnel zone plate lens for operation at 300 GHz, whose structure is supported on substrate made of an ultraporous silica foam with a nanocellulose thin film coating. The effective dielectric permittivity and loss of the substrate (ε r = 1.018 ± 0.003 and tan δ < 3 × 10 −4 at 300 GHz) is close to that of air. Experiments show that the fabricated Fresnel zone plate lens connected to a waveguide with total gain of 20 dB and angular beamwidth of 2.9°in good agreement with microwave simulations. The proposed lens structure has additional advantages such as small volume, ultralight weight, and simulations indicate 60 GHz bandwidth making it particularly appealing for radio front-ends of future 6G devices.

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“…The production of such gradient structures is not trivial, thus making heterogeneous lenses less attractive than their homogeneous counterparts based on low-permittivity materials. [11] Among dielectrics, silica has good electromagnetic properties (ε r = 3.8 and tan δ = 0.005 at 300 GHz) and thus it is a popular choice of structural materials in high-frequency applications. Lowering ε r and tan δ of SiO 2 can be achieved by 1) partially replacing easy-to-polarize Si─O bonds with Si─F bonds (e.g., by F doping); [12,13] 2) introducing voids (e.g., pores filled DOI: 10.1002/adpr.202200208 Several devices of the future generation wireless telecommunication technologies that use bands in THz frequencies for data transmission need low-loss and lowpermittivity materials to enable ideal conditions for the propagation of electromagnetic waves.…”

Section: Introductionmentioning

confidence: 99%

Porous Low‐Loss Silica–PMMA Dielectric Nanocomposite for High‐Frequency Bullet Lens Applications

Pálvölgyi

Kokkonen

Śliz

et al. 2023

Advanced Photonics Research

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Several devices of the future generation wireless telecommunication technologies that use bands in THz frequencies for data transmission need low‐loss and low‐permittivity materials to enable ideal conditions for the propagation of electromagnetic waves. Herein, a lightweight dielectric bullet‐shaped lens operating in the frequency range of 110–170 GHz is demonstrated to collimate electromagnetic waves, thus increasing the intensity of the electric field. The material of the lens is based on a composite of silica nanoshells and poly(methylmethacrylate) made by the impregnation of the nanoshells with the polymer followed by hot pressing in a mold. As the polymer acts only as an adhesive between the hollow nanospheres without filling the inner cavity of the shells and their interparticle spaces, the composite is highly porous (67%) and has low dielectric permittivity and loss tangent (1.5 and 4 × 10−3, respectively, below 200 GHz). The size of the collimated beam and the increase of the corresponding field strength are measured to vary from 2.2 to 1.2 mm and from 17.2 to 8.98 dB depending on the frequency of the waves (110–170 GHz).

show abstract

Study on the effect of the substrate material type and thickness on the performance of the filtering antenna design

Cited by 12 publications

References 16 publications

Design of circular-shaped microstrip patch antenna for 5G applications

Design of circular-shaped microstrip patch antenna for 5G applications

An Ultralow-Loss and Lightweight Cellulose-Coated Silica Foam for Planar Fresnel Zone Plate Lens Applications in Future 6G Devices

Porous Low‐Loss Silica–PMMA Dielectric Nanocomposite for High‐Frequency Bullet Lens Applications

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