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基于石英晶片镀膜工艺的Ka波段天线副反射面设计与实现

夏步刚 张德海 赵鑫 易敏 黄健

引用本文:
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基于石英晶片镀膜工艺的Ka波段天线副反射面设计与实现

夏步刚, 张德海, 赵鑫, 易敏, 黄健

Design and implementation of sub-reflector for Ka band antenna based on quartz wafer coating technology

Xia Bu-Gang, Zhang De-Hai, Zhao Xin, Yi Min, Huang Jian
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  • 卫星通信系统中使用频率选择表面作为抛物面天线的副反射面, 是实现频率复用、提高天线工作效率的有效手段. 本文运用模匹配法对频率选择表面单元进行分析计算, 并采用精细石英晶片镀膜工艺, 实现了Ka波段的频率选择表面构成的天线副反射面. 数值和实验结果均表明, 该反射面具有良好的角度稳定性及交叉极化特性, 同时通带内的插入损耗和阻带的回波损耗都处于较低水平, 保证了天线在其工作频带内的高增益. Ka波段的频率选择表面副反射面的研制顺应了当今卫星通信宽频带、窄波束和小型化的发展趋势.
    The design, fabrication and performance of a frequency selective surface (FSS) which is required to operate as broadband sub-reflector of Ka band antenna for satellite communication application is proposed and validated experimentally. In order to obtain this spatial filter which exhibits low insertion losses and insensitivities to the variation of oblique incident angle for TE and TM polarized wave, the mode-matching method is applied to the analysis of the geometrical structure and electrical parameters of FSS unit cell, and the fabrication process of this Ka FSS sub-reflector utilizing sophisticated quartz wafer coating technology is described. Electromagnetic field simulations and measurements results demonstrate that this FSS filter has virtually identical spectral responses in the two polarization planes.
    [1]

    Munk B A 2000 Frequency Selective Surfaces Theory and Design (New York: Wiley) pp51-57

    [2]

    Tang G M, Miao J G, Dong J M 2012 Acta Phys. Sin. 61 068402 (in Chinese) [唐光明, 苗俊刚, 董金明 2012 61 068402]

    [3]

    Xun N X, Feng X G, Wang Y S, Chen X, Gao J S 2011 Acta Phys. Sin. 60 114102 (in Chinese) [徐念喜, 冯晓国, 王岩松, 陈新, 高劲松 2011 60 114102]

    [4]

    Taylor P S, Austin A C M, Parker E A, Neve M J, Batchelor J C, Yiin J P, Sowerby K W 2012 Electron. Lett. 48 61

    [5]

    Tang G M, Miao J G, Dong J M 2012 Chin. Phys. B 21 128401

    [6]

    Wang X Z, Gao J S, Xu N X 2013 Acta Phys. Sin. 62 147307 (in Chinese) [王秀芝, 高劲松, 徐念喜 2013 62 147307]

    [7]

    Zhou H, Qu S B, Peng W D, Lin B Q, Wang J F, Ma H, Zhang J Q, Bai P, Wang X H, Xu Z 2012 Chin. Phys. B 21 054101

    [8]

    Agrawal V, Imbriale W 1979 IEEE Trans. Antenn. Propag. 27 466

    [9]

    Zimmerman M L, Lee S W, Fujikawa G 1992 IEEE Trans. Antenn. Propag. 40 1264

    [10]

    Wu T K 1994 U.S. Patent 5 373 302 [1994-12-13]

    [11]

    Porco C C, Helfenstein P, Thomas P C, Ingersoll A P, Wisdom J, West R, Neukum G, Denk T, Wagner R, Roatsch T, Kieffer S, Turtle E, McEwen A, Johnson T V, Rathbun J, Veverka J, Wilson D, Perry J, Spitale J, Brahic A, Burns J A, DelGenio A D, Dones L, Murray C D, Squyres S 2006 Science 311 1393

    [12]

    Ramaccia D, Bilotti F, Toscano A, Vegni L 2013 Compel 32 8

    [13]

    Skokic S, Sipus Z, Maci S, Bosiljevac M, Casaletti M 2012 IEEE 6th European Conference on Antennas and Propagation Prague March 26-30, 2012 p3299

    [14]

    Fang F 2009 Electro-Mech. Engin. 25 12 (in Chinese) [方芳 2009 电子机械工程 25 12]

    [15]

    Laskar J, Lee C H 2011 Compact Ku-band Transmitter Design for Satellite Communication Applications: From System Analysis to Hardware Implementation (Switzerland: Springer) pp1-5

    [16]

    Toptsidis N, Arapoglou P D, Bertinelli M 2012 Int. J. Satell. Commun. N. 30 131

    [17]

    Chambers A P, Callaghan S A, Otung I E 2006 IEEE Trans. Antenn. Propag. 54 1380

    [18]

    Hein M, Bayer H, Kraus A, Stephan R, Volmer C, Heuberger A, Volkert T 2010 IEEE Proceedings of the Fourth European Conference on Antennas and Propagation Barcelona, April 12-16, 2010 p1

    [19]

    Xia B G, Meng J, Zhang D H, Zhang J S 2013 Prog. Electromagn. Res. 139 599

    [20]

    Dickie R, Cahill R, Mitchell N, Gamble H, Fusco V, Munro Y, Rea S 2010 Electron. Lett. 46 472

    [21]

    Tian G Y, Li Y, Mandache C 2009 IEEE Trans. Magn. 45 184

    [22]

    Vardaxoglou J C 1997 Frequency Selective Surfaces: Analysis and Design (Vol. 997) (London: Research Studies Press) pp110-125

    [23]

    Mittra R, Chan C H, Cwik T 1988 Proc. IEEE 76 1593

  • [1]

    Munk B A 2000 Frequency Selective Surfaces Theory and Design (New York: Wiley) pp51-57

    [2]

    Tang G M, Miao J G, Dong J M 2012 Acta Phys. Sin. 61 068402 (in Chinese) [唐光明, 苗俊刚, 董金明 2012 61 068402]

    [3]

    Xun N X, Feng X G, Wang Y S, Chen X, Gao J S 2011 Acta Phys. Sin. 60 114102 (in Chinese) [徐念喜, 冯晓国, 王岩松, 陈新, 高劲松 2011 60 114102]

    [4]

    Taylor P S, Austin A C M, Parker E A, Neve M J, Batchelor J C, Yiin J P, Sowerby K W 2012 Electron. Lett. 48 61

    [5]

    Tang G M, Miao J G, Dong J M 2012 Chin. Phys. B 21 128401

    [6]

    Wang X Z, Gao J S, Xu N X 2013 Acta Phys. Sin. 62 147307 (in Chinese) [王秀芝, 高劲松, 徐念喜 2013 62 147307]

    [7]

    Zhou H, Qu S B, Peng W D, Lin B Q, Wang J F, Ma H, Zhang J Q, Bai P, Wang X H, Xu Z 2012 Chin. Phys. B 21 054101

    [8]

    Agrawal V, Imbriale W 1979 IEEE Trans. Antenn. Propag. 27 466

    [9]

    Zimmerman M L, Lee S W, Fujikawa G 1992 IEEE Trans. Antenn. Propag. 40 1264

    [10]

    Wu T K 1994 U.S. Patent 5 373 302 [1994-12-13]

    [11]

    Porco C C, Helfenstein P, Thomas P C, Ingersoll A P, Wisdom J, West R, Neukum G, Denk T, Wagner R, Roatsch T, Kieffer S, Turtle E, McEwen A, Johnson T V, Rathbun J, Veverka J, Wilson D, Perry J, Spitale J, Brahic A, Burns J A, DelGenio A D, Dones L, Murray C D, Squyres S 2006 Science 311 1393

    [12]

    Ramaccia D, Bilotti F, Toscano A, Vegni L 2013 Compel 32 8

    [13]

    Skokic S, Sipus Z, Maci S, Bosiljevac M, Casaletti M 2012 IEEE 6th European Conference on Antennas and Propagation Prague March 26-30, 2012 p3299

    [14]

    Fang F 2009 Electro-Mech. Engin. 25 12 (in Chinese) [方芳 2009 电子机械工程 25 12]

    [15]

    Laskar J, Lee C H 2011 Compact Ku-band Transmitter Design for Satellite Communication Applications: From System Analysis to Hardware Implementation (Switzerland: Springer) pp1-5

    [16]

    Toptsidis N, Arapoglou P D, Bertinelli M 2012 Int. J. Satell. Commun. N. 30 131

    [17]

    Chambers A P, Callaghan S A, Otung I E 2006 IEEE Trans. Antenn. Propag. 54 1380

    [18]

    Hein M, Bayer H, Kraus A, Stephan R, Volmer C, Heuberger A, Volkert T 2010 IEEE Proceedings of the Fourth European Conference on Antennas and Propagation Barcelona, April 12-16, 2010 p1

    [19]

    Xia B G, Meng J, Zhang D H, Zhang J S 2013 Prog. Electromagn. Res. 139 599

    [20]

    Dickie R, Cahill R, Mitchell N, Gamble H, Fusco V, Munro Y, Rea S 2010 Electron. Lett. 46 472

    [21]

    Tian G Y, Li Y, Mandache C 2009 IEEE Trans. Magn. 45 184

    [22]

    Vardaxoglou J C 1997 Frequency Selective Surfaces: Analysis and Design (Vol. 997) (London: Research Studies Press) pp110-125

    [23]

    Mittra R, Chan C H, Cwik T 1988 Proc. IEEE 76 1593

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出版历程
  • 收稿日期:  2013-06-18
  • 修回日期:  2013-07-14
  • 刊出日期:  2013-10-05

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