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Your search keyword '"Wu, Jun Wei"' showing total 11 results
Start Over Author "Wu, Jun Wei" Journal advanced optical materials
11 results on '"Wu, Jun Wei"'

1. A Long‐Range and Nearly Passive RFID‐Controlled Information Metasurface.

Author

Wang, Zheng Xing, Shen, Chuan Kui, Wu, Jun Wei, Xu, Hui, Cheng, Qiang, Ye, Terry Tao, and Cui, Tie Jun

Subjects
RADIO frequency identification systems, WIRELESS communications, REMOTE control
Abstract

Information metasurfaces (IMSs) have been considered to be a revolutionary technology for improving the spectral efficiency of sixth‐generation (6G) wireless communications due to their superior ability to manipulate electromagnetic (EM) waves. However, there are still problems to be solved before the widespread application of IMSs. The first is to reduce power consumption, and the second is to achieve a long‐range remote control. In this paper, a long‐range and nearly passive radio frequency identification (RFID)‐controlled IMS is proposed. The proposed IMS comprises four RFID tags and 8 × 8 elements, each of which is integrated with a single‐pole‐double‐throw switch chip to achieve 1‐bit phase reconfigurability. With the remote control of the RFID system, the IMS can be programmed to switch between three functionalities, including beam splitting, beamforming, and EM‐wave absorption. Experiments are performed and the beam‐splitting functionality is demonstrated. The measurement results indicate that the wireless communication between the RFID reader and the IMS is robust within 21.7 m. Additionally, the power consumption of the IMS is as low as 0.576 mW, which can be negligible. The scheme presented in this paper paves the way for the large‐scale applications of IMSs in 6G wireless communications. [ABSTRACT FROM AUTHOR]

Published
2024
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8. Digital Nonlinear Metasurfaces: Intensity‐Dependent Metasurface with Digitally Reconfigurable Distribution of Nonlinearity (Advanced Optical Materials 19/2019)

Author

Luo, Zhangjie, primary, Wang, Qiang, additional, Zhang, Xin Ge, additional, Wu, Jun Wei, additional, Dai, Jun Yan, additional, Zhang, Lei, additional, Wu, Hao Tian, additional, Zhang, Hao Chi, additional, Ma, Hui Feng, additional, Cheng, Qiang, additional, and Cui, Tie Jun, additional

Published
2019
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10. High Efficiency Polarization‐Encoded Holograms with Ultrathin Bilayer Spin‐Decoupled Information Metasurfaces.

Author

Wang, Zheng Xing, Wu, Jun Wei, Wu, Liang Wei, Gou, Yue, Ma, Hui Feng, Cheng, Qiang, and Cui, Tie Jun

Subjects
*DIGITAL holographic microscopy, *ELECTROMAGNETIC waves, *HOLOGRAPHY
Abstract

Information metasurfaces, including digital coding and programmable metasurfaces, have reformed the design theory of metasurfaces from effective medium to coding pattern, and bridged the physical and digital world. Metasurface hologram has shown great potential in imaging and manipulating electromagnetic waves. In this work, bilayer information metasurfaces are proposed to achieve polarization‐encoded holograms in microwave regime. The designed metasurfaces consist of 3‐bit spin‐decoupled meta‐atoms, which possess ultrathin profiles (0.14λ0) and high cross‐polarization transmittance (over 0.8). The incident wave, which is right‐handed circularly polarized or left‐handed circularly polarized, is encoded with code "0" or "1". The spin‐decoupled design is combined with diffuse scattering and holographic technology. Based on this, a novel algorithm is proposed to generate coding sequences according to the code of incident wave, to achieve different functionalities for corresponding circularly polarized channels. In this way, polarization‐encoded holograms, including diffuse scattering holograms (code "00"), single channel holograms (code "01" or "10"), and spin‐selective holograms (code "11"), are achieved. Simulated and measured results show that the maximum imaging efficiency can reach up to 65.1%, verifying the high efficiency of this holographic technology. This work is expected to open a way of realizing more complicated and higher efficiency information metasurface holography. [ABSTRACT FROM AUTHOR]

Published
2021
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11. Space-Frequency-Domain Gradient Metamaterials

Author

Wu, Hao Tian, primary, Wang, Dan, additional, Fu, Xiaojian, additional, Liu, Shuo, additional, Zhang, Lei, additional, Bai, Guo Dong, additional, Zhang, Cheng, additional, Jiang, Wei Xiang, additional, Jiang, Hao Lin, additional, Wu, Rui Yuan, additional, Wu, Jun Wei, additional, and Cui, Tie Jun, additional

Published
2018
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