A Multiband Millimeter-Wave Rectangular Dielectric Resonator Antenna with Omnidirectional Radiation Using a Planar Feed

Abdou, Tarek S.; Khamas, Salam K.

doi:10.3390/mi14091774

Cited by 3 publications

(2 citation statements)

References 38 publications

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“…Other the other hand, the reported antennas with omnidirectional radiation pattern 29 – 32 offer very low antenna gain, while the antenna 29 , and 32 have a gain value of less than 2dBi. A high radiation efficiency is offered by the antenna reported in 31 , however, the antenna suffers from the higher antenna profile. Among the antennas with omnidirectional radiation characteristics 29 – 32 , the proposed antenna offers a higher gain which ensures better wireless sensing capabilities.…”

Section: Performance Analysis and Comparisonmentioning

confidence: 99%

“…In 22 , a slotted tapered antenna unified with a feeding network built on stacked PCBs is proposed to achieve high gain and unidirectional radiation characteristics for the millimeter-wave IoT applications. While, higher order resonant mode 23 , slotted radiating patch 24 , modified binomial series-fed array 25 , glass-based multilayer antenna integrated with coupling vias 26 , SIW metamaterial 27 , lens operated planar antenna 28 , tapered rectangular monopole with slotted ground 29 , artificial magnetic-conductor 30 , dielectric-resonator 31 , and radial-waveguided dipole array 32 are investigated to achieve multi-band characteristics 23 , 24 , 29 – 31 , high gain 25 , 28 , process accuracy 26 , beam steering 27 , omnidirectional radiation patterns with high gain 29 – 32 . However, the majority of antennas described in the literature for millimeter-wave wireless communication, including Internet of Things applications, are primarily focused on high gain characteristics and provide unidirectional radiation patterns 22 – 28 .…”

Section: Introductionmentioning

confidence: 99%

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High gain quasi-omnidirectional dipole array fed by radial power divider for millimeter-wave IoT sensing

Sufian,

Hussain,

Choi

et al. 2024

Sci Rep

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This article presents the design and implementation of a dipole array antenna based on a radial waveguide power divider for millimeter-wave IoT sensing applications. The dipole array and radial waveguide power divider techniques are used in tandem to achieve high gain with omnidirectional radiation properties. The proposed antenna is comprised of eight non-uniform array dipole structures, a circular radiating loop, and shorting vias. The one-to-eight power divider is created with the shorting vias to feed the circularly arranged eight non-uniform dipole arrays simultaneously. The proposed antenna is simulated and manufactured on Rogers-RO3003C substrate with a thickness of 8 mils. Both simulated and tested results confirm that the proposed method enables the antenna to offer a quasi-omnidirectional pattern with a high peak gain of 5.42 dBi. The antenna offers an impedance bandwidth (S11 < ‒ 10 dB) of more than 1 GHz ranging from 27.93 to 29.13 GHz. Moreover, by optimizing the parameters of the power divider network the proposed antenna can be tuned between a wide bandwidth range of 14.53 GHz as the designed dipole array offering the operating bandwidth from 25.56 to 40.09 GHz. Due to its comprehensive set of performance attributes, particularly for the quasi-omnidirectional radiation characteristics, the presented antenna is a viable candidate for the 5G millimeter wave wireless IoT sensing applications. Additionally, this work will accommodate other researchers to explore the proposed method for developing high-gain omnidirectional antennas for millimeter-wave applications.

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