A novel miniaturized antipodal Vivaldi antenna with high gain

Yin, Zhangfei; Yang, Xue‐Xia; Yu, Fan; Gao, Steven

doi:10.1002/mop.32029

Cited by 8 publications

(5 citation statements)

References 13 publications

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“…In, 9 the exponential slot edge can improve the radiation pattern without increasing the size of the antenna. Similar slotted edge designs can be found in works 10–13 . In addition, different types of metamaterial structures have been integrated with Vivaldi antennas to improve the radiation performance.…”

Section: Introductionmentioning

confidence: 84%

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High‐gain UWB double slot vivaldi antenna loaded with metasurface and semi‐elliptical slots

Zhou

Xie

et al. 2023

Micro & Optical Tech Letters

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In this work, an ultra-wideband double slot Vivaldi antenna (DSVA) loaded with a novel wideband nonresonant metasurface is proposed to enhance the gain. The semi-elliptical slots are etched on both sides of the ground plane of the DSVA to improve the current distribution. In addition, the nonresonant metasurface composed of WiFi-shaped unit cells could maintain a stable high refractive index in the operating bandwidth of 1−18 GHz, which could bend the outgoing wave to the end-fire direction. Both the original antenna and the proposed antenna are simulated, fabricated, and characterized. The measured results are in good accordance with the simulated ones. The return losses of both antennas are less than −10 dB in the frequency range of 2−13.4 GHz, while the gain of the proposed antenna is improved from 13.6 to 16.3 dBi with a maximum gain enhancement of 3.1 dB.

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Section: Introductionmentioning

confidence: 84%

“…Similar slotted edge designs can be found in works. [10][11][12][13] In addition, different types of metamaterial structures have been integrated with Vivaldi antennas to improve the radiation performance. For example, an antipodal tapered slot antenna is loaded with a zero-index metamaterial (ZIM) structure in.…”

Section: Introductionmentioning

confidence: 99%

High‐gain UWB double slot vivaldi antenna loaded with metasurface and semi‐elliptical slots

Zhou

Xie

et al. 2023

Micro & Optical Tech Letters

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“…A highly directed Vivaldi antenna structure is obtained in [16] where the radiator is fed by a tapered microstrip line and slot line for impedance transformation from 50 Ω to about 80 Ω. In [17], a microstrip line to a symmetric double-sided slot line formation is used, which makes the input impedance conveniently matched to 50 Ω within a broadband. In [18], the design of a three-port diversity antenna capable of producing three-directional radiation pattern for vehicular communications is presented.…”

Section: Feeding Mechanism Of Vivaldi Antennasmentioning

confidence: 99%

“…Here to restrict the field radiation and concentrate the energy in the end-fire direction, coupling patches are introduced in the aperture area of the antenna. In [17], a Vivaldi antenna is presented where the gain of the antenna is enhanced by adding a via-loaded maple leaf shape on the edge of the radiator and ground plane. These maple leaves increase the gain at the upper-frequency band.…”

Section: Vivaldi Antenna With Special Structuresmentioning

confidence: 99%

Vivaldi antennas: a historical review and current state of art

Bhattacharjee

Bhawal

Karmakar

et al. 2020

Int. J. Microw. Wireless Technol.

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The progressions in the field of wireless technology can be highly attributed to the development of antennas, which can access high data rates, provide significant gain and uniform radiation characteristics. One such antenna called the Vivaldi antenna has attracted the utmost attention of the researchers owing to its high gain, wide bandwidth, low cross-polarization, and stable radiation characteristics. Over the years, different procedures have been proposed by several researchers to improve the performance of the Vivaldi antennas. Some of these different approaches are feeding mechanisms, integration of slots, dielectric substrate selection, and radiator shape. Correspondingly, the performance of a Vivaldi antenna can be increased by including dielectric lens, parasitic patch in between two radiators, corrugations, as well as metamaterials. This paper gives a systematic identification, location, and analysis of a large number of performance enhancement methods of Vivaldi antenna design depicting their concepts, advantages, drawbacks, and applications. The principal emphasis of this article is to offer an outline of the developments in the design of Vivaldi antennas over the last few years, where the most important offerings, mostly from IEEE publications, have been emphasized. This review work aims to reveal a promising path to antenna researchers for its advancement using Vivaldi antennas.

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“…Commonly used broadband microstrip antennas include antipodal and slot-coupled Vivaldi antennas; log-periodic arrays; feedline-coupled, multilayer-stacked patch antennas; and quasi-Yagi antennas [11][12][13][14][15][16]. Generally, Vivaldi and log-periodic array antennas are capable of operating over an ultra-broad bandwidth, but they may not be suitable for some applications where signal bandwidth is smaller.…”

Section: Introductionmentioning

confidence: 99%

Design and Development of a Wideband Planar Yagi Antenna Using Tightly Coupled Directive Element

et al. 2020

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In this paper, a novel concept on the design of a broadband printed Yagi antenna for S-band wireless communication applications is presented. The proposed antenna exhibits a wide bandwidth (more than 48% fractional bandwidth) operating in the frequency range 2.6 GHz–4.3 GHz. This is achieved by employing an elliptically shaped coupled-directive element, which is wider compared with other elements. Compared with the conventional printed Yagi design, the tightly coupled directive element is placed very close (0.019λ to 0.0299λ) to the microstrip-fed dipole arms. The gain performance is enhanced by placing four additional elliptically shaped directive elements towards the electromagnetic field’s direction of propagation. The overall size of the proposed antenna is 60 mm × 140 mm × 1.6 mm. The proposed antenna is fabricated and its characteristics, such as reflection coefficient, radiation pattern, and gain, are compared with simulation results. Excellent agreement between measured and simulation results is observed.

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A novel miniaturized antipodal Vivaldi antenna with high gain

Cited by 8 publications

References 13 publications

High‐gain UWB double slot vivaldi antenna loaded with metasurface and semi‐elliptical slots

High‐gain UWB double slot vivaldi antenna loaded with metasurface and semi‐elliptical slots

Vivaldi antennas: a historical review and current state of art

Design and Development of a Wideband Planar Yagi Antenna Using Tightly Coupled Directive Element

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