Design of a simple circularly polarised dual‐frequency reconfigurable microstrip patch antenna array for millimetre‐wave applications

Famoriji, Oluwole John; Yang, Shitan; Li, Yang; Chen, Wenhao; Fadamiro, Akinwale O.; Zhang, ZhongXiang; Lin, Fujiang

doi:10.1049/iet-map.2018.5973

Cited by 12 publications

(2 citation statements)

References 37 publications

(38 reference statements)

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“…A 4-element circularly polarized dual-frequency reconfigurable microstrip patch antenna array with dualfrequency reconfigurability at 27 and 35 GHz is suggested for mm-wave usage. In terms of their reconfigurable behavior with related return loss, radiation pattern features, and 3 dB axial ratio polarization bandwidth, patch antenna arrays behave better than individual elements [18]. Antennas for X-band frequency applications are developed, with rectangular and E-shaped patch arrays constructed from 2×2 mm 2 Roger RT5880 sheet with a thin coating of copper applied over it, and the feed line is implemented using microstrip lines [19].…”

Section: Introductionmentioning

confidence: 99%

Design of higher gain linearly polarized 2×2 microstrip patch array antenna for wireless communication

Gani,

Hegde

2024

IJECE

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The fifth-generation technology is popular and best as far as data rates are concerned for wireless applications. To meet the increased demand of the modern world for faithful communication, this research work is carried out. In this approach, a single patch, 1×2 array, and 2×2 array are designed using a low-cost FR4 dielectric substrate ( =4.4) covering the 3.3–3.8 GHz frequency band. Due to the lack of gain from arrays in the present research, an attempt is made to achieve excellent gain from arrays with a minimum number of patches. First, the gain of a single inset-fed antenna is compared with another normal single patch of the same thickness but with an additional air dielectric medium. Next, the second single patch is extended to obtain a rectangular 1×2 array and a 2×2 array antenna. A second single patch measuring 50×32.5×0.8 mm is designed assuming an infinite ground plane. It has 3mm air gap between the patch strip and the ground. Air acts as a second dielectric layer that reduces power loss. This allows a maximum gain of 15.2 dB with a return loss of -22 dB. Also, antenna efficiency and bandwidth are 91% and 267.69 MHz, respectively.

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Section: Introductionmentioning

confidence: 99%

Design of higher gain linearly polarized 2×2 microstrip patch array antenna for wireless communication

Gani,

Hegde

2024

IJECE

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“…At the same time, in the practical application, there are different requirements for the in-band and out-of-band RCS reduction in antennas. It is a big problem to achieve accurate in-band RCS reduction on the premise of ensuring the radiation performance of the broadband antenna [10,11]. It is of great military significance to study and design a solution that takes into account miniaturization and accurate reduction in wideband RCS [12][13][14].…”

Section: Introductionmentioning

confidence: 99%

A Low RCS and Array-Insensitive FSS Wideband Radome

Gong,

Zhang,

Wang

et al. 2023

Electronics

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In order to further expand the RCS reduction model of the miniature broadband antenna, a four-notch shaped FSS radome insensitive to the number of array elements is designed based on the multi-layered medium Green’s function and the transflective coefficient of the finite radome is derived. The calculated results are in good agreement with the infinite array, showing broadband transmission performance in both C-band and X-band. The electric field distribution and far-field distribution of a finite FSS array are given and the effects of a 5 × 5 array in a V-shaped structure on the surface of a miniature broadband antenna on its gain coefficient and RCS reduction characteristics are calculated numerically. The results show that the designed radome exhibits good array element insensitivity and far-field scattering reduction characteristics and achieves significant in-band and out-of-band RCS accurate reduction under the premise of constant antenna radiation performance. At normal incidence, the single-station RCS in the passband and stopband are as low as −35 dB and −32.66 dB, respectively. The maximum reduction in the transmission band reaches 20.96 dB under oblique incidence and the projection size of the radome decreases with the increase in the bottom angle of the radome but the RSC reduction performance is basically unaffected and can be adjusted flexibly according to actual needs. The above results provide a theoretical basis and technical support for the application of FSS radome in RCS reduction in micro wideband antennas.

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