Innovative Reconfigurable Metasurface 2-D Beam-Steerable Reflector for 5G Wireless Communication

Rotshild, David; Rahamim, Efraim; Abramovich, Amir

doi:10.3390/electronics9081191

Cited by 20 publications

(20 citation statements)

References 34 publications

(60 reference statements)

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“…Decreasing the value of C int makes the value of C d more dominant in the total unit cell capacitance C and increasing its dynamic tuning range. Using a dielectric substrate with ε r = 2 and reducing the unit cell and patch sizes reduces the value of C int [11,[17][18][19]36]. The reduction in the patches prevented the varactor from being placed directly on the adjacent patches' edges (blind pad), as in other works [8,15,28,30].…”

Section: Unit Cell and Ms Reflector Concept And Designmentioning

confidence: 97%

“…On the other hand, a large TC allows for a reduction in Q and unit cell losses while maintaining a high dynamic phase reflection range. Several methods add reconfiguring and tuning to MS, such as PIN switches, MEMS switches, liquid crystal materials, piezoelectric materials, and varactor diodes [8,9,[12][13][14][15][16][17][18][19][20][21][22]. The liquid crystal method is used in the K-band and above and can be realized in MS as a tuning dielectric substrate, without any external element in the front, but is more challenging to implement [16].…”

Section: Introductionmentioning

confidence: 99%

“…A varactor diode allows for a continuous and high-tuning-capacitance ratio and fits the continuous reflection phase method in the proposed MS reflector [8,14,15,[17][18][19][28][29][30]. The varactor diodes allow for high-frequency work up to 70 GHz, a conventional PCB assembly, and extremely low consuming power [31], and thus leads to a focus on the varactor diode in this study.…”

Section: Introductionmentioning

confidence: 99%

“…However, the varactor diode suffers from relatively high losses compared to the switches. The losses effect is reduced by decreasing Q [11,[17][18][19]. The reduction in Q is justified due to the very high tunability of the varactor diode capacitance value with a high TC parameter.…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Ultra-Wideband Reconfigurable X-Band and Ku-Band Metasurface Beam-Steerable Reflector for Satellite Communications

Rotshild

Abramovich

2021

Electronics

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A continuously reconfigurable metasurface reflector based on unit cell mushroom geometry that was integrated with a varactor diode is presented in this paper. The unit cell of the metasurface was designed and optimized to operate in the X-band and Ku-band, improving satellite communication’s quality of service. The losses mechanisms of continuous control over the unit cell phase reflection in beam steering resolution are considered and the analysis results are presented. The unit cell design parameters were analyzed with an emphasis on losses and dynamic reflection phase range. The unit cell magnitude and phase reflection are shown in the wide frequency bandwidth and showed a good agreement between all the measurements and the simulations. This metasurface enabled a high dynamic range in the unit cell resonant frequency range from 7.8 to 15 GHz. In addition, the reflection phase and absorption calibration are demonstrated for multiple operating frequencies, namely, 11 GHz, 12 GHz, and 13.5 GHz. Furthermore, design trade-offs and manufacturing limitations were considered. Finally, a beam-steering simulation using the designed metasurface is shown and discussed.

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Section: Unit Cell and Ms Reflector Concept And Designmentioning

confidence: 97%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Ultra-Wideband Reconfigurable X-Band and Ku-Band Metasurface Beam-Steerable Reflector for Satellite Communications

Rotshild

Abramovich

2021

Electronics

Self Cite

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“…The most common name for this type of device is a reflectarray. It can be based on partially reflecting surfaces [11], frequency-selective surfaces [12,13], and metasurfaces with integrated tunable elements [14][15][16]. However, the operating frequencies of such devices currently are limited to the Ku-band.…”

Section: Introductionmentioning

confidence: 99%

Millimeter-Wave Reflector Based on a Ferroelectric Material with Electrical Beam Steering

et al. 2021

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Millimeter waves are increasingly used in modern telecommunication systems for wireless data transmission. However, higher path loss, especially caused by non-line-of-sight scenarios, remains challenging. The design of an electrically controllable reflector for the millimeter-wave range is elaborated and presented in this manuscript. The reflector design was based on distributed ferroelectric ceramic elements and could be used in a frequency range up to 100 GHz. The issue of the ferroelectric reflector impedance matching was analyzed in detail. Two possible implementations of the reflector for indoor and outdoor communication systems were considered and simulated. The prototype of the proposed reflector for an operating frequency of 60 GHz was manufactured. Both simulation and measurement results demonstrated the beam steering by the proposed ferroelectric reflector.

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Mechatronic Reconfigurable Intelligent‐Surface‐Driven Indoor Fifth‐Generation Wireless Communication

Jeong

Park

Phon

et al. 2022

Advanced Intelligent Systems

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Reconfigurable intelligent surface‐assisted wireless networks have been proposed to overcome the current technical issues in fifth‐generation (5G) wireless communication systems. Generally, the beam control functions of a reconfigurable intelligent surface require the independent phase control of the unit cells, and each unit cell requires an active device. Although reconfigurable intelligent surfaces are considered a promising solution for 5G and sixth‐generation (6G) wireless communication, their practical implementation faces a bottleneck at high frequencies (e.g., with the millimetre‐wave spectrum) because they require a large number of active devices, leading to high costs, parasitic effects, increased design complexity, and modulated signal distortion. Herein, a mechatronic reconfigurable intelligent surface is reported for indoor millimetre‐wave wireless communication. Our mechatronic device strengthens the innovative reflective beam control functions through rotatable unit structures and rack gear systems. Furthermore, the criteria required for future 5 G wireless communication are experimentally verified by transmitting and receiving quadrature phase‐shift keying 16‐/32‐/64‐quadrature amplitude modulation signals based on 5 G new radio (NR) frequency range two standards for indoor environments.

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Innovative Reconfigurable Metasurface 2-D Beam-Steerable Reflector for 5G Wireless Communication

Cited by 20 publications

References 34 publications

Ultra-Wideband Reconfigurable X-Band and Ku-Band Metasurface Beam-Steerable Reflector for Satellite Communications

Ultra-Wideband Reconfigurable X-Band and Ku-Band Metasurface Beam-Steerable Reflector for Satellite Communications

Millimeter-Wave Reflector Based on a Ferroelectric Material with Electrical Beam Steering

Mechatronic Reconfigurable Intelligent‐Surface‐Driven Indoor Fifth‐Generation Wireless Communication

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