2017
DOI: 10.2528/pierc17061301
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Wideband High Gain Antenna Subarray for 5g Applications

Abstract: Abstract-Wideband arrays have recently received considerable attention in 5G applications to cover larger frequency bands. This paper presents a novel design of a high gain and wideband antenna subarray from 23 GHz to 32 GHz, which covers the frequency bands proposed by the Federal Communications Commission (FCC) for 5G communications. The proposed subarray consists of four radiating elements with wideband and high gain characteristics. These elements are composed of two stacked patches, which are fed using th… Show more

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Cited by 29 publications
(10 citation statements)
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“…The single substrate layer antennas presented in [77] and [31] are of moderate size, gain, and bandwidth. To improve the performance of a multielement antenna the multilayer antenna is designed in [39], [78], [79] but, the overall size of antennas is large. In [39], proximity coupled multi-element antenna is designed to enhance the gain at the cost of increased size.…”
Section: ) Multi-element Antennasmentioning
confidence: 99%
“…The single substrate layer antennas presented in [77] and [31] are of moderate size, gain, and bandwidth. To improve the performance of a multielement antenna the multilayer antenna is designed in [39], [78], [79] but, the overall size of antennas is large. In [39], proximity coupled multi-element antenna is designed to enhance the gain at the cost of increased size.…”
Section: ) Multi-element Antennasmentioning
confidence: 99%
“…Consequently, seven steered beams of a10° step (i.e., −30°, −20°, −10°, 0°, +10°,+20°, and +30°) are needed, which are implemented by placing seven input ports in the proposed Rotman lens. Moreover, the 1 × 4 subarray antenna, which is designed for wideband 5G applications and is presented in [48], achieves a gain of more than 11 dBi over the entire band. Based on array theory [49], eight elements separated by a half-wavelength achieves an array factor of 10*log(8) = 9 dB.…”
Section: Rotman Lens Design Using Particle Swarm Optimzationmentioning
confidence: 99%
“…In this study, an antenna is designed in such a way which gives a larger bandwidth with enough gain. For 5G bandwidth must be large so that number of applications can be accessed [12,13]. There are plenty of techniques by which antenna bandwidth can be made wider such as parasitic patch, stacked patches, aperture stacked patches, aperture coupling, decreasing relative permittivity etc.…”
Section: Introductionmentioning
confidence: 99%