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低有效介电常数复合材料的聚波特性研究

刘涛 曹祥玉 马嘉俊 王伟

刘涛, 曹祥玉, 马嘉俊, 王伟. 低有效介电常数复合材料的聚波特性研究[J]. 电子与信息学报, 2009, 31(3): 632-635. doi: 10.3724/SP.J.1146.2007.01836
引用本文: 刘涛, 曹祥玉, 马嘉俊, 王伟. 低有效介电常数复合材料的聚波特性研究[J]. 电子与信息学报, 2009, 31(3): 632-635. doi: 10.3724/SP.J.1146.2007.01836
Liu Tao, Cao Xiang-yu, Ma Jia-jun, Wang Wei. Study on Characteristics of Converging-Wave Based on Low Effective Permittivity Metamaterials[J]. Journal of Electronics & Information Technology, 2009, 31(3): 632-635. doi: 10.3724/SP.J.1146.2007.01836
Citation: Liu Tao, Cao Xiang-yu, Ma Jia-jun, Wang Wei. Study on Characteristics of Converging-Wave Based on Low Effective Permittivity Metamaterials[J]. Journal of Electronics & Information Technology, 2009, 31(3): 632-635. doi: 10.3724/SP.J.1146.2007.01836

低有效介电常数复合材料的聚波特性研究

doi: 10.3724/SP.J.1146.2007.01836
基金项目: 

国家自然科学基金(60671001),空军工程大学电讯工程学院博士创新基金(200603),陕西省自然科学基础研究(2005F21)和西安市工业攻关项目(GG06020)资助课题

Study on Characteristics of Converging-Wave Based on Low Effective Permittivity Metamaterials

  • 摘要: 该文通过建立结构模型,分析了辐射源辐射功率密度与有效介电常数和有效磁导率的关系,然后分析了辐射功率密度与此种属性材料介电常数、厚度、辐射源位置及工作频率的关系。结果表明,辐射源辐射功率密度与有效介电常数和有效磁导率的比值成正比关系,相对低的介电常数可以显著改善辐射源前向辐射功率密度,最大辐射功率密度是厚度的周期函数,而与辐射源位置关系不大;获得较大辐射功率密度的工作频带是非常窄的。理论上解释了人工构造的低介电常数材料作为天线覆层提高增益的原因。
  • Lin Qing-chun, Zhu Fang-ming, and He Sai-ling. A newphotonic bandgap cover for a patch antenna with a photonicbandgap substrate [J].Journal of Zhejiang University ScienceA.2004, 5:269-273[2]Weily A R, Horvath L, and Esselle K P, et al.. A planarresonator antenna based on a woodpile EBG material[J].IEEE Trans. on Antenna and Propagation.2005, 53(1):216-223[3]Th`evenot M, Cheype C, and Reineix A, et al.. Directivephotonic-bandgap antennas [J].IEEE Trans. on MicrowaveTheory and Technology.1999, 47(11):2115-2122[4]Cheype C, Serier C, and Thevenot M, et al.. Anelectromagnetic bandgap resonator antenna[J].IEEE Trans.on Antenna and Propagation.2002, 50(9):1285-1290[5]Boutayeb H, Denidni T A, and Sebak A R, et al.. Design ofelliptical electromagnetic bandgap structures for directiveantennas [J].IEEE Antenna and Wireless PropagationLetters.2005, 4:93-96[6]Hu Jun, Yan Chun-sheng, and Lin Qing-chun. A new patchantenna with metamaterial cover [J]. Journal of ZhejiangUniversity Science A, 2006, 7: 89-94.[7]Feresidis A P and Vardaxoglou J C. High gain planar antennausing optimised partially reflective surfaces[J].IEE Proc.Microwave. Antenna Propagation.2001, 148(6):345-350[8]Wang S, Feresidis A P, and Goussetis G, et al.. High-gainsubwavelength resonant cavity antennas based onmetamaterial ground planes [J].IEE Proc. -Microw.Antennas Propag.2006, 153(1):1-6[9]Al A, Bilotti F, and Engheta N, et al.. Metamaterial coversover a small aperture[J].IEEE Trans. on Antenna andPropagation.2006, 54(6):1632-1643[10]Ziolkowski R W and Kipple A D. Application of doublenegative materials to increase the power radiated byelectrically small antennas[J].IEEE Trans. on Antenna andPropagation.2003, 51(10):2626-2640[11]Stuart H R and Pidwerbetsky A. Electrically small antennaelements using negative permittivity resonators[J].IEEETrans. on Antenna and Propagation.2006, 54(6):1644-1653[12]李斌. 微波复合介质材料及其应用研究. [博士论文], 西安电子科技大学, 2006.Li Bin. Study of application and characteristics ofMetamaterials[D], Xidian University, 2006.[13]Enoch S, Tayeb G, and Sabouroux P, et al.. A metamaterialfor directive emission[J]. Physical Review Letters, 2002,89(21): 3901-3904.[14]Baccarelli P, Burghignoli P, and Frezza F. Effects of leakywavepropagation in metamaterial grounded slabs excited bya dipole source[J]. IEEE Trans. on Antenna and Propagation,2005, 53(3): 32-44.[15]Lovat G, Burghignoli P, and Jackson D R. Fundamentalproperties and optimization of broadside radiation fromuniform leaky-wave antennas [J]. IEEE Trans. on Antennaand Propagation, 2006, 54(5): 32-44.
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出版历程
  • 收稿日期:  2007-11-28
  • 修回日期:  2008-06-04
  • 刊出日期:  2009-03-19

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