High gain cylindrical dielectric resonator integrated with horn for multiband wireless applications

Chauhan, Monika; Mukherjee, Biswajeet

doi:10.1002/mmce.22161

Cited by 7 publications

(8 citation statements)

References 23 publications

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“…Designs reported in 21 and 36 are having pbw higher than designed TEM horn, but power handling capacity of the antennas is not discussed. Dielectric resonator antenna (DRA) discussed by Chauhan et al 37 is a multiband resonant antenna which covers different frequency bands 2.2–4.6, 7.3–7.7, and 8.6–10.9 GHz, tend to be dispersive in nature. Proposed TEM horn antenna in our case is an ultra wideband antenna, which covers a frequency band of 0.135–1.5 GHz and is nondispersive in nature.…”

Section: Antenna Analysis and Experimental Resultsmentioning

confidence: 99%

High power balanced TEM horn antenna for ultra wide band radiator

Singh

Chandra

Mitra

et al. 2022

Micro & Optical Tech Letters

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A balanced transverse electromagnetic (TEM) horn type antenna is designed and developed for a 120 kV, 66 Ω high power ultra wideband (UWB) radiator. This antenna consists of a coaxial to parallel plate unzipper BALUN followed by an exponentially tapered TEM horn structure. Analysis of this antenna in time and frequency domain is performed using CST Microwave Studio. This antenna is having a power handling capacity of 1000 MW, with percentage bandwidth of 167%. This antenna has a gain of ~10 dB at 1 GHz frequency. Return loss performance of better than −10 dB is observed in 150 MHz to 1 GHz frequency range. Effective radiation of short pulses (<5 ns) with very fast rise time (300–500 ps) has been demonstrated using this high‐power antenna. Practical results at 220 MW power are presented in this article. Directional performance of this antenna is practically established through peak power patterns in horizontal and vertical plane.

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Section: Antenna Analysis and Experimental Resultsmentioning

confidence: 99%

High power balanced TEM horn antenna for ultra wide band radiator

Singh

Chandra

Mitra

et al. 2022

Micro & Optical Tech Letters

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“…To meet the development requirement of high gain, the gain enhancement approaches of the DR antenna have been widely studied, 8‐16 which generally fall into three categories. Among them, the most common approach is to integrate the DR with a horn 8‐10 . Another approach uses the multilayer stacked anisotropic resonator to increase the radiation from the sidewalls of the DR 11‐13 .…”

Section: Introductionmentioning

confidence: 99%

“…[3][4][5][6][7] Nevertheless, the conventional DR antenna with uniform medium radiates through both the top wall and sidewalls, which has relatively low gain compared to the MP antenna. 3 To meet the development requirement of high gain, the gain enhancement approaches of the DR antenna have been widely studied, [8][9][10][11][12][13][14][15][16] which generally fall into three categories. Among them, the most common approach is to integrate the DR with a horn.…”

Section: Introductionmentioning

confidence: 99%

“…Among them, the most common approach is to integrate the DR with a horn. [8][9][10] Another approach uses the multilayer stacked anisotropic resonator to increase the radiation from the sidewalls of the DR. [11][12][13] Furthermore, benefiting from multimode nature, designing the DR antenna to operate at the higher-order modes is a convenient and effective way to enhance the gain. [14][15][16] However, the majority of the resultant antennas are complicated in structure or high in profile, which will be a major obstacle to the DR antenna in certain spacelimited applications.…”

Section: Introductionmentioning

confidence: 99%

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A differential‐fed dual‐polarized antenna with gain enhancement using hollow dielectric patch resonator

Wang

Tang

Yang

et al. 2021

Int J RF Microw Comput Aided Eng

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A differential-fed dual-polarized dielectric patch (DP) antenna with high gain, wide bandwidth, and high isolation is investigated in this article. Based on the analysis of the anisotropic property of the DP antenna, further exploration of gain enhancement is carried out. The introduction of the square air hole in the substrate to obtain a hollow DP resonator is a crucial technique. It not only increases the electromagnetic radiation from the sidewalls of the DP resonator to further improve the gain to 8.9 dBi, but also shifts the dominant TM 101 mode upward to get close to the higher-order TM 121 mode to achieve bandwidth expansion of 19.4%. By using the differential-fed scheme to excite the TM 101 mode, TM 121 mode and their degenerate modes, dual-polarization operation and high isolation level can be obtained simultaneously. K E Y W O R D Sdielectric patch (DP) resonator, differential-fed, dual-polarized antenna, high gain, low-profile, wideband

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“…DRAs are characterized by high radiation efficiency, low metallic losses, compact size, and ease of excitation method. It provides broad bandwidth (BW), low quality factor ( Q ‐factor), and high gain compared to traditional microstrip antennas 3,4 . A survey on the DRA modeling using numerical methods, applications, and development techniques are introduced in References 5‐7 .…”

Section: Introductionmentioning

confidence: 99%

Asymmetric liquid flow control polarization reconfigurable cylindrical dielectric resonator antenna for wireless communications

Malhat

Zainud-Deen

2020

Int J RF Microw Comput Aided Eng

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This paper introduces a cylindrical dielectric resonator antenna (CDRA) with three reconfigurable polarization cases using liquid flow control. The CDRA volume has two pairs of drilling cylindrical holes with unsymmetrical radii and positions from the CDRA center along the two orthogonal diagonals. The liquid is flowing alternately in one‐cylindrical hole pair and is extracted from the other for polarization control. The two hole pairs radii and locations are optimized for minimum axial ratio (AR) of 1.5 dB at 5.8 GHz. Four polarization cases are achieved for left‐hand circular (LHCP), right‐hand circular (RHCP), and linear polarization (LP). The insertion of air holes pair in case (A) and case (B) widens the bandwidth (BW) to 1.28 GHz with high gain of 6.6 dBi in θ = 0, ϕ = 0 direction. The sequential rotation array arrangements are employed for circular polarization BW enhancement. Three arrangements are investigated. To improve the AR BW arrangement (III) introduces an improvement of 2 GHz compared with 60 MHz for the single CDRA element with a peak gain of 13.3 dBi.

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High gain cylindrical dielectric resonator integrated with horn for multiband wireless applications

Cited by 7 publications

References 23 publications

High power balanced TEM horn antenna for ultra wide band radiator

High power balanced TEM horn antenna for ultra wide band radiator

A differential‐fed dual‐polarized antenna with gain enhancement using hollow dielectric patch resonator

Asymmetric liquid flow control polarization reconfigurable cylindrical dielectric resonator antenna for wireless communications

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