Design and Analysis of High Gain Slotted SIW Array Antennas at Ka-Band

Given the interference avoidance capacity, high gain, and dynamical reconfigurability, phased array antennas (PAAs) have emerged as a key enabling technology for future broadband mobile applications. This is especially important at millimeter-wave (mm-wave) frequencies, where the high power consumption and significant path loss impose serious range constraints. However, at mm-wave frequencies the phase and amplitude control of the feeding currents of the PAA elements is not a trivial issue because electrical beamforming requires bulky devices and exhibits relatively narrow bandwidth. In order to overcome these limitations, different optical beamforming architectures have been presented. In this paper we review the basic principles of phased arrays and identify the main challenges, that is, integration of high-speed photodetectors with antenna elements and the efficient optical control of both amplitude and phase of the feeding current. After presenting the most important solutions found in the literature, we analyze the impact of the different noise sources on the PAA performance, giving some guidelines for the design of optically fed PAAs.

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Ka-Band Lightweight High-Efficiency Wideband 3D Printed Reflector Antenna

International Journal of Antennas and Propagation ◽

10.1155/2017/7360329 ◽

2017 ◽

Vol 2017 ◽

pp. 1-7 ◽

Cited By ~ 1

Author(s):

Yu Zhai ◽

Ding Xu ◽

Yan Zhang

Keyword(s):

High Efficiency ◽

Near Field ◽

Side Lobe ◽

High Gain ◽

Reflector Antenna ◽

Field Analysis ◽

Side Lobe Level ◽

Ka Band ◽

3D Printed ◽

Reflecting Surface

This paper presents a lightweight, cost-efficient, wideband, and high-gain 3D printed parabolic reflector antenna in the Ka-band. A 10 λ reflector is printed with polylactic acid- (PLA-) based material that is a biodegradable type of plastic, preferred in 3D printing. The reflecting surface is made up of multiple stacked layers of copper tape, thick enough to function as a reflecting surface (which is found 4 mm). A conical horn is used for the incident field. A center-fed method has been used to converge the energy in the broadside direction. The proposed antenna results measured a gain of 27.8 dBi, a side lobe level (SLL) of −22 dB, and a maximum of 61.2% aperture efficiency (at 30 GHz). A near-field analysis in terms of amplitude and phase has also been presented which authenticates the accurate spherical to planar wavefront transformation in the scattered field.

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Switchable T-Slot for Dual-Circularly-Polarized Slot-Array Antennas in Ka-Band

IEEE Antennas and Wireless Propagation Letters ◽

10.1109/lawp.2021.3101156 ◽

2021 ◽

pp. 1-1

Author(s):

Miguel Ferrando-Rocher ◽

Jose Ignacio Herranz-Herruzo ◽

Alejandro Valero-Nogueira ◽

Bernat Bernardo

Keyword(s):

Ka Band ◽

Circularly Polarized ◽

Array Antennas

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High Gain Planar Antenna Array for Ka Band SAR Applications

2018 China International SAR Symposium (CISS) ◽

10.1109/sars.2018.8552003 ◽

2018 ◽

Author(s):

Sheng Ye ◽

Junyi Hu ◽

Liang Li ◽

Yanbing Ma ◽

Kun Qin

Keyword(s):

Antenna Array ◽

High Gain ◽

Planar Antenna ◽

Ka Band ◽

Planar Antenna Array

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Ka-band Vivaldi Antenna with Novel Core Element for High-Gain

Loughborough Antennas & Propagation Conference (LAPC 2017) ◽

10.1049/cp.2017.0236 ◽

2017 ◽

Author(s):

Manh-Ha Hoang ◽

Kansheng Yang ◽

M. John ◽

P. McEvoy ◽

M. Ammann

Keyword(s):

High Gain ◽

Core Element ◽

Ka Band ◽

Vivaldi Antenna

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A Ka-Band Cylindrical Paneled Reflectarray Antenna

Electronics ◽

10.3390/electronics8060654 ◽

2019 ◽

Vol 8 (6) ◽

pp. 654 ◽

Cited By ~ 2

Author(s):

Francesco Greco ◽

Luigi Boccia ◽

Emilio Arnieri ◽

Giandomenico Amendola

Keyword(s):

High Gain ◽

Cylindrical Symmetry ◽

Radiation Efficiency ◽

Ka Band ◽

Cylindrical Reflector ◽

Geometric Relation ◽

Reflectarray Antenna ◽

Parabolic Reflectors ◽

Reflecting Surface ◽

Continuous Metal

Cylindrical parabolic reflectors have been widely used in those applications requiring high gain antennas. Their design is dictated by the geometric relation of the parabola, which relate the feed location, f, to the radiating aperture, D. In this work, the use of reflectarrays is proposed to increase D without changing the feed location. In the proposed approach, the reflecting surface is loaded with dielectric panels where the phase of the reflected field is controlled using continuous metal strips of variable widths. This solution is enabled by the cylindrical symmetry and, with respect to rectangular patches or to other discrete antennas, it provides increased gain. The proposed concept has been evaluated by designing a Ka-band antenna operating in the Rx SatCom band (19–21 GHz). A prototype has been designed and the results compared with the ones of a parabolic cylindrical reflector using the same feed architecture. Simulated results have shown how this type of antenna can provide higher gain in comparison to the parabolic counterpart, reaching a radiation efficiency of 65%.

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Wide-Angle Scanning Phased Array Antenna using High Gain Pattern Reconfigurable Antenna Elements

Scientific Reports ◽

10.1038/s41598-019-54120-2 ◽

2019 ◽

Vol 9 (1) ◽

Author(s):

ByungKuon Ahn ◽

In-June Hwang ◽

Kwang-Seok Kim ◽

Soo-Chang Chae ◽

Jong-Won Yu ◽

...

Keyword(s):

Phased Array ◽

High Gain ◽

Array Antenna ◽

Reconfigurable Antenna ◽

Wide Angle ◽

Phased Array Antenna ◽

Design Guideline ◽

Phased Array Antennas ◽

Array Antennas ◽

Scanning Range

AbstractThis paper presents a wide-angle scanning phased array antenna using high gain pattern reconfigurable antenna (PRA) elements. Using PRA elements is an attractive solution for wide-angle scanning phased array antennas because the scanning range can be divided into several subspaces. To achieve the desired scanning performance, some characteristics of the PRA element such as the number of switching modes, tilt angle, and maximum half-power beamwidth (HPBW) are required. We analyzed the required characteristics of the PRA element according to the target scanning range and element spacing, and presented a PRA element design guideline for phased array antennas. In accordance with the guideline, the scanning range was set as ±70° and a high gain PRA element with three reconfigurable patterns was used to compose an 8x1 array antenna with 0.9 λ0 spacing. After analyzing whether the active element patterns meet the guideline, the array antenna was fabricated and measured to demonstrate the scanning performance. The fabricated array can scan its beam from -70° to 70° by dividing the scanning range into three subspaces. It shows that even if the array antenna has large element spacing, the desired scanning performance can be obtained using the elements designed under the guideline.

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