三重光子晶体分形缝隙阵列天线的设计

doi:10.12677/JA.2019.83003

期刊菜单

三重光子晶体分形缝隙阵列天线的设计
Design of the Triple Photonic Crystal Fractal Slot Array Antenna

DOI: 10.12677/JA.2019.83003, PDF, 被引量科研立项经费支持
作者: 林斌：厦门大学嘉庚学院，信息科学与技术学院，福建漳州
关键词: 三重光子晶体天线；分形缝隙结构；十字分形缝隙阵列结构；移动通信系统；射频识别系统；Triple Photonic Crystal Antenna； Fractal Slot Structure； Cross Fractal Slot Array Structure； Mobile Communication System； RFID System

摘要: 本文针对多频段兼容移动通信系统和RFID系统对天线的性能要求，创造性地提出了一种新型三重光子晶体天线结构，并将其与十字分形缝隙阵列结构相结合，设计了一款三重光子晶体分形缝隙阵列天线，制作了天线样品并进行了测试。根据天线样品测试结果，该款天线能够覆盖第二代、第三代、第四代、第五代移动通信系统所有工作频段和RFID系统三个工作频段，在各个工作频带都具有较大的工作带宽和较强的辐射能力。该款天线在所有工作频段都具有高稳定辐射特性，有望用于兼具RFID读写器功能的手机中。

Abstract: According to the performance requirements of the antennas for the multi-band compatible mobile communication system and RFID system, a novel triple photonic crystal antenna is proposed crea-tively, and combined with the cross fractal slot array structure, a triple photonic crystal fractal slot array antenna is designed, and the antenna samples are made and tested. According to the test results of antenna samples, this antenna can work in the frequency bands of the 2G, the 3G, the 4G and the 5G mobile communication system and three working frequency bands of RFID system at the same time, and has a large working bandwidth and strong radiation power in each working frequency band. This antenna has high stable radiation characteristics in all working frequency bands and is expected to be used in mobile phones with RFID reader and writer functions.

文章引用：林斌. 三重光子晶体分形缝隙阵列天线的设计[J]. 天线学报, 2019, 8(3): 19-25. https://doi.org/10.12677/JA.2019.83003

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