High gain antipodal Vivaldi antenna with novel V‐shaped
            <scp>air‐slot</scp>

Huang, Xiaodong; Cao, Jinru; Zhong, Wang; Jin, Xiuhua

doi:10.1002/mmce.22818

Cited by 4 publications

(2 citation statements)

References 27 publications

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“…A tapered slot structure with a band-resonant cavity is also used to improve bandwidth and gain [ 6 ]. By slotting on the dielectric substrate [ 7 ], the electromagnetic waves propagate on the substrate between the antenna slot gaps, thereby improving the gain. The miniaturized Vivaldi antenna [ 8 ] uses bent feed lines and Gaussian curves to save space, and it replaces the traditional exponential function with a Gaussian function to increase the current path and to improve the port impedance characteristics.…”

Section: Introductionmentioning

confidence: 99%

Ultra-Wideband and High-Gain Vivaldi Antenna with Artificial Electromagnetic Materials

Zhang

et al. 2023

Micromachines

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An ultra-wideband and high-gain Vivaldi antenna with artificial electromagnetic material, suitable for ground-penetrating radar (GPR) systems, is proposed. Directors loaded inside the antenna gradient slot direct electromagnetic waves by inducing current to improve gain. The artificial electromagnetic material, also called metamaterial, is composed of multiple “H”-shaped units arranged in a certain regular pattern, loaded at the antenna aperture. The artificial electromagnetic units affect the antenna radiation waves by changing the refractive index to improve radiation directivity. The four Vivaldi units are arranged into a horn-shaped array, and each two units are orthogonally fed to realize dual polarization. Experimental results demonstrate that the antenna has good impedance matching of S11≤−10 dB in 0.9–4 GHz, and the maximum realized gain can reach 15.2 dBi.

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Section: Introductionmentioning

confidence: 99%

Ultra-Wideband and High-Gain Vivaldi Antenna with Artificial Electromagnetic Materials

Zhang

et al. 2023

Micromachines

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“…The Vivaldi antenna appears to be a good choice for microwave imaging applications because of its wide array of features such as wide bandwidth, narrow beam-width, directive radiation pattern, low cost, low profile, and small size, as discussed in [18] - [23]. Several modifications on AVAs like metamaterial slabs enhanced AVA [24], slotted AVA [25], lens loaded Vivaldi Antenna [26 -27], Artificial Intelligence based Vivaldi Antenna design optimization [28] are reported in the literature. Due to its flexibility in performance enhancement, end-fire radiation pattern and having a planar structure, an AVA is proposed in this work operating in the UWB range (3.1 -10.6 GHz).…”

Section: Introductionmentioning

confidence: 99%

Concealed Object Detection With Microwave Imaging Using Vivaldi Antennas Utilizing Novel Time-Domain Beamforming Algorithm

Asok

Dey

2022

IEEE Access

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A time-domain novel beamforming algorithm for ultra-wideband (UWB) microwave imaging is furnished in this paper. A monostatic and bistatic antenna setup is utilized to transmit and receive custom UWB pulses. This setup is employed to image various metallic and non-metallic threats attached to a human body. The imaging results demonstrate that the proposed beamforming algorithm allows effective reconstruction of different targets for both monostatic and bistatic cases. An ultra-wideband high gain Antipodal Vivaldi Antenna (AVA) is used as the transducer for the proposed imaging setup. The designed transducer demonstrates measured impedance bandwidth from 660 MHz to 15 GHz (182%) with a peak gain of 15 dBi at 8 GHz. The quality and accuracy of the proposed beamforming algorithm is tested outside the anechoic chamber just to make it more convincing in a real-world dynamic scenario. The result shows that different concealed materials can be detected accurately with the beamforming algorithm. To the best of the authors' knowledge, the proposed algorithm can effectively add up the target responses to obtain a clear and distinct image of the metallic and non-metallic targets.INDEX TERMS Antipodal Vivaldi Antenna (AVA), beamforming algorithm, bistatic, concealed,high gain, human body, metallic, monostatic, non-metallic, novel beamforming algorithm, Ultra-wideband (UWB).

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A corrugated and lens based miniaturized antipodal Vivaldi antenna for 28 GHz and 38 GHz bands applications

2023

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The paper presents a dualband and compact antipodal Vivaldi antenna (AVA) array by using a dielectric lens (DL) and corrugations for 5G applications. The proposed novel antenna provides very high efficiency and it alleviates beam titling very effectively. Its efficiency is in the range of 95.93%–97.52% whereas the H plane beam titling is ± 1 ° $\pm 1{}^{\circ}$ over most of the frequency range. The antenna frequency response is improved by incorporating corrugations which results in the antenna miniaturization. The designed AVA array size is 2.86 × 3.58 × 0.06 λ g 3 ${{\lambda }_{g}}^{3}$ (for lower guided frequency). The proposed dualband antenna operates from 24.17 GHz to 29.37 GHz and 30.76 GHz to 40.58 GHz. These frequency bands cover 28 GHz and 38 GHz bands of 5G communications. Next, the front-to-back ratio is improved significantly which further results in the gain enhancement. Also, the grooves in the feeding network minimize reverse power reflections. The radiation pattern is stable and it shows that the designed antenna is a directional antenna. The antenna is designed, simulated, and tested by using a network analyzer and anechoic chamber. The testing and simulated results indicate that the proposed AVA array is the best candidate to integrate it in 5G devices.

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High gain antipodal Vivaldi antenna with novel V‐shaped air‐slot

Cited by 4 publications

References 27 publications

Ultra-Wideband and High-Gain Vivaldi Antenna with Artificial Electromagnetic Materials

Ultra-Wideband and High-Gain Vivaldi Antenna with Artificial Electromagnetic Materials

Concealed Object Detection With Microwave Imaging Using Vivaldi Antennas Utilizing Novel Time-Domain Beamforming Algorithm

A corrugated and lens based miniaturized antipodal Vivaldi antenna for 28 GHz and 38 GHz bands applications

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