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所属单位：[1] Guangdong Key Laboratory of Millimeter-Waves and Terahertz, the School of Electronic and Information Engineering, South China University of Technology, Guangzhou, China; [2] Computer and Information College, Hohai University, Nanjing, China; [3] State Key Laboratory of Electronic Films and Integrated Devices, University of Electronic Science and Technology of China, Chengdu, China

发表刊物：International Journal of RF and Microwave Computer-Aided Engineering

关键字：Antenna feeders - Microwave antennas - Millimeter waves - Phase change materials - Slot antennas - Waveguides

摘要：In this article, a millimeter-wave frequency-reconfigurable metasurface antenna by electrically controlling vanadium dioxide (VO2) is proposed and studied. As a phase change material, VO2 is an insulator at room temperature but can turn into high conductivity metallic state when activated by continuous direct current (DC) voltage. By integrating the VO2 film between two simple rectangle metasurface cells, a frequency-reconfigurable paired metasurface structure (FRPMS) is achieved. The FRPMS can be considered as one unit when VO2 film is activated to metallic state while as two independent cells when VO2 film is in insulating state. In this way, the FRPMS can operate, respectively at 28 and 38 GHz with independent tunability. Moreover, a coplanar and staggered DC bias circuit with little effect on radiation is designed to switch the operating modes of VO2 easily. The antenna is fed by a stepped waveguide with ridges through a loop slot, which is suitable for dual-band feeding with large frequency ratio. One prototype is fabricated and measured for demonstration. When the VO2 film is in metallic state, the measured working band covers from 28.5 to 29.6GHz with the maximum gain of about 7.1dBi. When cooled down to insulating state, the antenna can work in a higher band from 36.7 to 38.3GHz with the maximum gain of about 7.9dBi. Due to the advantages of simple structure, high gain and easy tuning, the antenna can be expected to use in mmW wireless communication. ? 2022 Wiley Periodicals LLC.

文献类型：Journal article (JA)

卷号：32

期号：12

ISSN号：10964290

是否译文：否