一种超宽带小型化探地雷达天线的设计

doi:10.11720/wtyht.2014.4.21

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摘要通过对蝶形偶极子天线复合加载的方式形成一种小型化的探地雷达天线，多种加载方式的引入不但使天线具有宽频带的性能，而且设计的天线尺寸与理论计算尺寸相比也大大减小。在天线后方引入背腔设计，增加了天线的方向性和抗干扰能力。所设计的天线具有1.5~4 GHz的频带宽度，且天线的方向性良好。设计的天线已成功应用于LTD探地雷达2.2 GHz天线系统和3 GHz的液态危险品检测天线系统中。

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Abstract：A kind of miniaturized GPR antenna was designed through complex loading to the bow-tie dipole. The introduction of multiple loading methods not only makes the antenna acquire the performance of broadband but also greatly decreases the size of antenna compared with the theoretical calculation size. By introducing back cavity behind the antenna, the directivity and anti-jamming capability of the antenna are enhanced. The designed antenna possesses a 1.5 GHz~4 GHz frequency band width and a good direction. The designed antenna is successfully applied to the antenna system of 2.2 GHz LTD series of GPR. This designed antenna can be also used in the dangerous liquid goods inspection system of 3 GHz LTD series of GPR.

收稿日期: 2013-10-20 出版日期: 2014-08-10

P631.3

基金资助:国家“十二五”专项预演项目（51307050402）

作者简介: 彭宇（1983-），男，工程师，从事探地雷达天线、收发机的研发设计和探地雷达的探测方法研究工作。

引用本文:

彭宇, 王蕾, 郭福强, 胡通海. 一种超宽带小型化探地雷达天线的设计[J]. 物探与化探, 2014, 38(4): 750-753.
PENG Yu, WANG Lei, GUO Fu-Qiang, HU Tong-Hai. The design of an ultra-wideband miniaturized GPR antenna. Geophysical and Geochemical Exploration, 2014, 38(4): 750-753.

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https://www.wutanyuhuatan.com/CN/10.11720/wtyht.2014.4.21 或 https://www.wutanyuhuatan.com/CN/Y2014/V38/I4/750

[1] Harry M J.探地雷达理论与应用[M].雷文泰,董孝忠,等,译.北京:电子工业出版社,2011.
[2] Hertl I,Strycek M.UWB antennas for ground penetrating radar application//19th International Conference on Applied Electromagnetics and Communications. Dubrovnik,2007:1-4.
[3] Guangyou F.New design of the antipodal Vivaldi antenna for a GPR System[J].Microwave Opt Technol, 2005,44 (2): 136-139.
[4] Turk A S.Ultra-wideband Vivaldi antenna design for multisensory adaptive ground-penetrating impulse radar[J].Microwave Opt Technol,2006,48(5):834-839.
[5] Turk A S,Sahinkaya D A,Nazli H,et al.Investigation of convenient antenna designs for ultra-wide band GPR systems//4th International Workshop on Advanced Ground Penetrating Radar,Naples,2007:192-196.
[6] Turk A S.Ultra-wideband TEM horn design for ground penetrating impulse radar systems[J].Microwave OPT Technol,2004,41(5): 333-336.
[7] Kao C,Li J,Liu R,et al.Design and analysis of UWB TEM horn antenna for ground penetrating radar applications//IEEE International Geoscience and Remote Sensing Symposium, Boston,2008-07-07.
[8] Phelan M,Su H,LoVetri J. Near field analysis of a wideband log-spiral antenna for 1~2 GHz GPR//Conference on Electrical and Computer Engineering.Canadian: Winnipeg, 2002-05-12,(1):336-341.
[9] Fabrizio Congedo.Giuseppina Monti. Modified Bowtie Antenna for GPR Applications//IEEE 13th International Conference,2010-06-21.
[10] Salman A O,Bicak Emrullah,Sezgin Mehmet.Textile Antenna for the Multi-sensor (Impulse GPR&EMI) Subsurface Detection System//IEEE 13th International Conference,2010-06-21.
[11] Chen G,Richard C.A 900 MHz Shielded Bow-tie Antenna System for Ground Penetrating Radar//IEEE 13th International Conference,2010-06-21.
[12] Chang D C,Lee J H,Le S H.The Study of Wideband Bowtie Antenna for ITDAMS//Microwave and Millimeter Wave Technology, ICMMT 4th International Conference,2004:54-57.
[13] John D K,Ronald J M. 天线(上册)[M].章文勋,译.北京:电子工业出版社,2004:226.
[14] Yasuhro Nishioka,Toru Uno,Takehito Iguchi.Characteristics of Cavity-Isolated and Cavity-Connected Bow-Tie Antennas for Subsurface Pulse Radar[J].Electronics and Communications in Japan,2002,85(8).

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