Dual-Band Dual-Polarized Scalable Antenna Subarray for Compact Millimeter-Wave 5G Base Stations

Hu, Hsin-Nan; Lai, Fei-Peng; Chen, Yen‐Sheng

doi:10.1109/access.2020.3009431

Cited by 23 publications

(12 citation statements)

References 33 publications

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“…Furthermore, achieving wideband performance in dual polarization would be an indispensable feature for both mm-Wave and sub-6GHz 5G/6G base stations [67,68]. This would allow for communication at the same frequency band but in orthogonal polarizations, vastly increasing the throughput of the system.…”

Section: Figure 9 Spiral Dipoles With Rectangular Ring Tdf Unit Cell ...mentioning

confidence: 99%

Wideband Reflectarrays for 5G/6G: A Survey

Theoharis

Raad

Tubbal

et al. 2022

IEEE Open J. Antennas Propag.

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Section: Figure 9 Spiral Dipoles With Rectangular Ring Tdf Unit Cell ...mentioning

confidence: 99%

Wideband Reflectarrays for 5G/6G: A Survey

Theoharis

Raad

Tubbal

et al. 2022

IEEE Open J. Antennas Propag.

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“…It is experimentally demonstrated that the polarization mismatch becomes a substantial loss factor that heavily affects the overall quality of the wireless link at mmWave frequencies, and dual-polarized phased arrays can provide more reliable Quality of Service (QoS) for mmWave 5G mobile phones than their single-polarized counterparts [4], [5]. Recently, several dualband dual-polarized mmWave antennas have been proposed for 5G applications [6]- [12]. These designs use either stacked patches [6]- [11] or planar dipoles [12].…”

Section: Introductionmentioning

confidence: 99%

“…Recently, several dualband dual-polarized mmWave antennas have been proposed for 5G applications [6]- [12]. These designs use either stacked patches [6]- [11] or planar dipoles [12]. However, their height profiles are in the range of 2 − 4 mm, whereas the typical thickness of the printed circuit boards (PCBs) used in cell phones is around 1 mm.…”

Section: Introductionmentioning

confidence: 99%

A Low-Profile Dual-Band Dual-Polarized Quasi-Endfire Phased Array for mmWave 5G Smartphones

Rao

Sarabandi

2022

IEEE Access

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This paper presents a very low-profile (0.105λ 0 at 28 GHz) dual-band dual-polarized millimeter-wave phased array for 5G smartphones. The array element is based on two distinct dual-band antennas to realize two orthogonal linear polarizations. A planar folded dipole with a parasitic strip is used to produce horizontally polarized radiation, and a novel hexagonal bridge antenna is devised to generate vertically polarized radiation while maintaining a very low profile. A prototype of a 1 × 4 phased array is designed and implemented on a multilayer laminate using standard printed circuit board process. The real estate of the array is kept within 6.5 mm × 23 mm × 1.12 mm. For both polarizations, the −10 dB bandwidth covers 25.4-30.84 GHz and 38-40 GHz with peak gains of 11.31 and 11.93 dBi at two center frequencies, respectively. The overlapped 3 dB scan ranges between both polarizations are ±45 • at 28 GHz and ±39 • at 39 GHz. This work considers a number of important design challenges of implementing low-cost mmWave antennas in smartphones, providing a practical solution to mmWave 5G mobile devices.

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“…However, since the S-band and X-band antennas are mounted in different spaces on the ship mast, the aperture area of the system is increased, resulting in a high RCS. In addition, since the antenna elements are not generally in the form of expandable modules, whenever the array antenna is applied to a differently sized platform, the full array antennas for a new platform must be re-developed [20]. Even in the case of failure of individual antenna elements, the entire system must be repaired or replaced if not modularized.…”

Section: Introductionmentioning

confidence: 99%

Design of a Polarization-Selective EM Transparent Mesh-Type E-Shaped Antenna for Shared-Aperture Radar Applications

Wang

Kim

Kim³

et al. 2022

Applied Sciences

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In this paper, we propose a polarization-selective electromagnetic (EM) transparent mesh-type E-shaped antenna unit-cell in a shared aperture. The proposed antenna unit-cell, which can be expanded to a larger array in a modular way, has one S-band antenna on the upper layer and nine X-band antennas on the lower layers. The simple E-shaped structure, which has a low profile with a good bandwidth, is used for the antenna elements. However, due to the limited aperture size of the stacked configuration, the lower-layer elements can be physically blocked by the upper-layer element. To reduce this blockage effect, the S-band element is rotated 90 degrees with respect to X-band elements so that the polarizations between the S- and X-band elements are perpendicular to each other. Moreover, to minimize performance degradation due to the blockage effect, a mesh structure is applied for S-band elements for EM transparent characteristics, thereby improving EM transparency from −30 dB to −1.5 dB. The extended via cavity wall is also employed outside the nine X-band elements to minimize the mutual coupling and to reduce antenna size. To confirm the effectiveness of the proposed design, the proposed antenna unit-cell is fabricated, and the radiation characteristics are measured, in a full anechoic chamber. The average bore-sight gains in the S- and X-band are 5 dBi and 4.5 dBi, respectively. The results confirm that the proposed design is suitable for shared-aperture radar applications.

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Dual-Band Dual-Polarized Scalable Antenna Subarray for Compact Millimeter-Wave 5G Base Stations

Cited by 23 publications

References 33 publications

Wideband Reflectarrays for 5G/6G: A Survey

Wideband Reflectarrays for 5G/6G: A Survey

A Low-Profile Dual-Band Dual-Polarized Quasi-Endfire Phased Array for mmWave 5G Smartphones

Design of a Polarization-Selective EM Transparent Mesh-Type E-Shaped Antenna for Shared-Aperture Radar Applications

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