Millimeter Wave Beam Steering Reflectarray Antenna Based on Mechanical Rotation of Array

Abbasi, Muhammad Inam; Dahri, M. Hashim; Jamaluddin, Mohd Haizal; Seman, Norhudah; Kamarudin, Muhammad Ramlee; Sulaiman, N. H.

doi:10.1109/access.2019.2945318

Cited by 33 publications

(14 citation statements)

References 24 publications

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“…Moreover, the asymmetric patch reflectarray attains a wider reflection phase span with a lower design complexity than these two dual band designs. Two other similar works reported in [4] and [19] offer good bandwidth and gain performance with low design complexity, but for just a single polarization operation. Moreover, these two works present a reflectarray antenna with a conventional type of element, such as circular ring and rectangular patch, which offer a very narrow reflection phase range.…”

Section: Comparison Of Asymmetric Patch Reflectarray Antenna With Othmentioning

confidence: 91%

“…The only limitation associated with asymmetric patch reflectarray antenna is its narrow beamwidth, which tends to increase the number of sectors in a microcell. This limitation could be avoided by using a beamsteering strategy in the reflectarray antenna [6,19]. A wide reflection phase range, as in asymmetric patch reflectarray, would be beneficial for acquiring wide angle beamsteering operation.…”

Section: Receive Signal Strength (Rss) Measurementmentioning

confidence: 99%

“…Simulations of unit cell element and full reflectarray are performed by CST Microwave Studio within a frequency range of 24 to 28 GHz. The selected frequency range is considered due to its application in 5G communications [4,19]. The proposed design of the reflectarray antenna has also been experimentally verified.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

A Novel Asymmetric Patch Reflectarray Antenna with Ground Ring Slots for 5G Communication Systems

et al. 2020

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The narrow bandwidth and low gain performances of a reflectarray are generally improved at the cost of high design complexity, which is not a good sign for high-frequency operation. A dual resonance asymmetric patch reflectarray antenna with a single layer is proposed in this work for 5G communication at 26 GHz. The asymmetric patch is developed from a square patch by tilting its one vertical side by a carefully optimized inclination angle. A progressive phase range of 650° is acquired by embedding a circular ring slot in the ground plane of the proposed element for gain improvement. A 332-element, center feed reflectarray is designed and tested, where its high cross polarization is suppressed by mirroring the orientation of asymmetric patches on its surface. The asymmetric patch reflectarray offers a 3 dB gain bandwidth of 3 GHz, which is 4.6% wider than the square patch reflectarray. A maximum measured gain of 24.4 dB has been achieved with an additional feature of dual linear polarization. Simple design with wide bandwidth and high-gain of asymmetric patch reflectarray make it suitable to be used in 5G communications at high frequencies.

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Section: Comparison Of Asymmetric Patch Reflectarray Antenna With Othmentioning

confidence: 91%

Section: Receive Signal Strength (Rss) Measurementmentioning

confidence: 99%

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A Novel Asymmetric Patch Reflectarray Antenna with Ground Ring Slots for 5G Communication Systems

et al. 2020

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“…For mechanically controlling [4], the beam scanning is generally achieved by the rotation of the array, the rotation of the feed horn, or combines the two mentioned approaches. In [5], the proposed RA antenna achieves a beam scanning range of more than ±60° based on the mechanical rotation of the array. In [6], a wide-angle beam-scanning RA based on the mechanical rotation of the feed antenna was proposed, and the gain variation was less than 1.7 dB within the scan coverage of ±45°.…”

Section: Introductionmentioning

confidence: 99%

1-Bit Wideband Reconfigurable Reflectarray Design in Ku-Band

Zhu

et al. 2022

IEEE Access

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In this paper, a 1-bit wideband electronically reconfigurable reflectarray (RRA) in Ku-band is proposed. In order to achieve the wideband and reconfigurable characteristics, the stacked microstrip structure and a 1-bit "microstrip line-slot line-microstrip line" phase shifter (MSMPS) were introduced in this design. A novel "receiving-phase shift-transmitting" unit cell was gotten by connecting two stacked microstrip structures using MSMPS. Due to the receiving and transmitting parts are perpendicular to each other, the polarization rotation characteristic was demonstrated. To avoid the blockage of the feed horn, it was placed above the reflecting surface array with an offset angle of 25° to the normal direction. A 16 × 16 obliquely-fed RRA was designed and fabricated. The measured 1-dB gain bandwidth of the RRA is 15.4%. The measured results show that the fabricated prototype can achieve beam scanning from -20° to 50° in the elevation plane, and ±50° beam scanning in the azimuth plane.

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“…Such a beam-forming approach can have many advantages over traditional tunable antenna array architectures, including a significant reduction in hardware required per element and increased efficiency [6]. Researchers have investigated different techniques for beam steering antennas such as the use of nonlinear dielectric materials [7][8][9], the integration of Radio Frequency Microelectro Mechanical Systems (RF MEMS) as switches [10,11], loading varactor diodes with the patch elements and varying the varactor capacitance by using various biasing [12,13], using aperture coupled elements where the tuning circuit can be located on the nonresonating surface of the element in order to control the contributed phase from each element [14], and using mechanical movement of the antenna [15]. Some other researchers have also proposed the use of PIN diodes for beam switching where the diodes can be switched ON and OFF using an external biasing circuit, and hence, the reflectarray beam can be controlled [16][17][18][19].…”

Section: Introductionmentioning

confidence: 99%

Development of a Pin Diode-Based Beam-Switching Single-Layer Reflectarray Antenna

Abbasi

Ismail

Kamarudin

2020

International Journal of Antennas and Propagation

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This paper presents a practical demonstration for the design and development of a switchable planar reflectarray using PIN diodes in the X-band frequency range. Waveguide scattering parameter measurements for the unit cells and far-field measurements of the periodic reflectarrays have been carried out to verify the predicted results. Reflectarray unit cell measurements demonstrated a frequency tunability of 0.36 GHz with a dynamic phase range of 226°. On the other hand, the designed 6 × 6 periodic reflectarray has been shown to achieve beam switching from +6° to −6° with different switching states of PIN diodes. This type of beam switching can be used in satellite communication for specific region coverage.

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Millimeter Wave Beam Steering Reflectarray Antenna Based on Mechanical Rotation of Array

Cited by 33 publications

References 24 publications

A Novel Asymmetric Patch Reflectarray Antenna with Ground Ring Slots for 5G Communication Systems

A Novel Asymmetric Patch Reflectarray Antenna with Ground Ring Slots for 5G Communication Systems

1-Bit Wideband Reconfigurable Reflectarray Design in Ku-Band

Development of a Pin Diode-Based Beam-Switching Single-Layer Reflectarray Antenna

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