PDF下载分享

[1]倪鹏程,刘昆,杜雨洺,等.闪电对n79频段5G微带天线的电磁耦合效应研究[J].成都信息工程大学学报,2022,37(03):270-275.[doi:10.16836/j.cnki.jcuit.2022.03.006]
　NI Pengcheng,LIU Kun,DU Yuming,et al.Investigation at Lightning Electromagnetic Coupling Effects of 5G Microstrip Antenna Working on n79 Band[J].Journal of Chengdu University of Information Technology,2022,37(03):270-275.[doi:10.16836/j.cnki.jcuit.2022.03.006]

点击复制

闪电对n79频段5G微带天线的电磁耦合效应研究

成都信息工程大学学报[ISSN:1006-6977/CN:61-1281/TN] 卷: 37 期数: 2022年03期页码: 270-275 栏目: 电子信息科学与技术出版日期: 2022-06-06

Title:: Investigation at Lightning Electromagnetic Coupling Effects of 5G Microstrip Antenna Working on n79 Band

文章编号:: 2096-1618(2022)03-0270-06

作者:: 倪鹏程¹; 刘昆¹; 杜雨洺¹; 孙筱枫¹; 董志诚²; (1.成都信息工程大学电子工程学院,四川成都 610225; 2.西藏大学信息科学技术学院,西藏拉萨 850000)

Author(s):: NI Pengcheng¹; LIU Kun¹; DU Yuming¹; SUN Xiaofeng¹; DONG Zhicheng²; (1.College of Electronic Engineering, Chengdu University of Information Technology, Chengdu610225,China; 2.College of Information Science and Technology, Tibet University, Lasa 850000,China)

关键词:: 雷击电磁脉冲; 5G; 微带天线; 极化可重构天线; 雷电耦合效应

Keywords:: LEMP; 5G; microstrip antenna; polarized reconfigurable antenna; lightning coupling effect

分类号:: TN821

DOI:: 10.16836/j.cnki.jcuit.2022.03.006

文献标志码:: A

摘要:: 基于团队前期研究,建立天线在闪电通道附近的电磁耦合模型,详细分析所设计的n79频段(4.8～4.9 GHz)微带天线在不同极化状态下与闪电之间的电磁耦合特征。结果表明:天线为垂直极化状态时,其电场与闪电通道附近电场极化匹配,天线后端感应电压峰值便会大于同一时刻下的圆极化状态下的感应电压峰值。天线在不同极化状态下与闪电通道的耦合电压与其极化偏转角度有关,当天线表面电流的主要方向与闪电通道电场极化方向平行时,天线后端感应电压达到最大,而当天线表面电流的主要方向与闪电通道垂直时,天线后端的感应峰值电压最小。并提出一种基于天线极化可重构的防雷新方法。

Abstract:: In this paper, based on the lightning return stroke electromagnetic model, the lightning channel-communication tower-antenna model is established. The electromagnetic coupling characteristics between the n79 band(4.8-4.9 GHz)microstrip antenna designed in this paper and lightning in different polarization states are analyzed in detail. When the antenna is in linear polarization state, the polarization state of its electric field matches that of the electric field near the lightning channel, the peak value of the coupling voltage at the back end of the antenna will be greater than the peak value of the coupling voltage in the circular polarization state at the same time. The coupling voltage of the antenna with the lightning channel in different polarization states is related to its polarization deflection angle, when the main direction of the current on the antenna surface is parallel to the lightning channel, the induced voltage at the back end of the antenna reaches the maximum. When the main direction of the surface current of the antenna is perpendicular to the lightning channel, the induced peak voltage at the back end of the antenna is the smallest. Based on this, a new method of lightning protection based on antenna polarization reconfigurable is proposed.

参考文献/References:

[1] 刘元林.移动通信基站遭受雷击时的空间电磁分布及影响[J].硅谷,2010(3):8-9.
[2] Sun X N,Wang Q G,Zhou X,et al.Response Characteristics of Dipole Antenna Exposed to Nuclear Electromagnetic Pulse[J].Journal of Microwaves,2014,30(6):51-54.
[3] S Sebastiani.Protecting VHF antennas from EMP[C].International Symposium on Electromagnetic Compatibility.IEEE,1991:297-303.
[4] Podgorski A S,Podgorski E M.Lightning and Nemp Protection of HF and VHF Antennas - Numerical Simulation[C].International Telecommunications Energy Conference. IEEE, 1986:433-436.
[5] 张其林,冯建伟,赵中阔,等.分形闪电通道模型的建立及其电磁辐射特征[J].大气科学学报,2010,33(6):719-724.
[6] Zhang Z,Tian Y,Wang C,et al.Research on the Distribution Characteristics of Electromagnetic Environment in the Lightning Return Stroke Near-Field Area[C]. International Symposium on Antennas and Propagation.IEEE,2019:1-4.
[7] Liu K,Li S W,Qie X S,et al.Analysis and Investigation on Lightning Electromagnetic Coupling Effects of a Dipole Antenna for a Wireless Base Station[J].IEEE Transactions on Electromagn Compatibility,2018,60(6):1842-1849.
[8] Tsuge R,Baba Y,Kudo T.Development of Enhanced Lightning Protection System for a Wireless Base Station and its Performance Evaluation Using the FDTD Method[J].IEEJ T Electr Electr,2020,15(11):1622-1629.
[9] Gomes C,Diego A G.Lightning protection scenarios of communication tower sites; human hazards and equipment damage[J].Safety Sci,2011,49(10):1355-1364.
[10] A Civil.The effects of lightning discharges on control & communication cables and antenna systems[C].International Power Modulator and High Voltage Conference.IEEE,2016:588-593.
[11] 彭涛.一种具有防雷保护功能的对称振子天线设计[J].科技创新与应用,2017(2):95-96.
[12] B Wang,S W Cheung,W Wang,et al.A high-power wide beamwidth circularly polarized antenna with lightning protection[C].2017 11th European Conference on Antennas and Propagation.IEEE,2017:1933-1935.
[13] J Y Ong.Performance Analysis of Stacked Capacitive Antenna for Lightning Remote Sensing[C].International Conference on Electrical Engineering and Computer Science.IEEE,2018:305-308.
[14] C A Morales Rodriguez.Lightning warning system based on a slow antenna[C].International Symposium on Lightning Protection.IEEE,2015:153-156.
[15] Heidler F.Traveling current source model for LEMP calculation[C].proc.6th Int.zurich symp.Electromagn compat,1985:157-162.
[16] Ge L,Luk K M.A Band-Reconfigurable Antenna Based on Directed Dipole[J].IEEE Transactions on Antennas and Propagation,2014,62(1):64-71.

相似文献/References:

[1]王韧,唐涛,敬守钊,等.具有共形能力的阻抗可调天线[J].成都信息工程大学学报,2022,37(02):155.[doi:10.16836/j.cnki.jcuit.2022.02.007]

备注/Memo

收稿日期:2022-03-13
基金项目:四川省科技计划资助项目(2021YFG0355)

更新日期/Last Update: 2022-06-06