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0.14THz基模多注折叠波导行波管的理论与模拟研究

颜胜美 苏伟 王亚军 徐翱 陈樟 金大志 向伟

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0.14THz基模多注折叠波导行波管的理论与模拟研究

颜胜美, 苏伟, 王亚军, 徐翱, 陈樟, 金大志, 向伟

Theoretical and simulation study of 0.14 THz fundamental mode multi-beam folded waveguide traveling wave tube

Yan Sheng-Mei, Su Wei, Wang Ya-Jun, Xu Ao, Chen Zhang, Jin Da-Zhi, Xiang Wei
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  • 为解决THz行波管工作电流过小、输出功率低等问题, 提出了基模多注工作模式的折叠波导行波管. 首先, 获得了基模多注折叠波导色散特性的等效传输线计算模型, 并与数值模拟结果进行了比较; 然后, 对基模多注折叠波导的传输特性进行了模拟计算; 最后, 通过模拟和理论计算完成了0.14 THz基模多注折叠波导行波管的注波互作用特性分析. 电子注参数为12 mA, 15.75 kV时, 获得的3 dB带宽为25 GHz (128–153 GHz), 最大增益为33.61 dB, 最大峰值功率为23 W; 电子注参数为30 mA, 15.75 kV时, 在0.14 THz处获得了38 dB增益, 最大脉冲输出功率为63.1 W. 对比同条件下基模单注折叠波导行波管, 3 dB带宽提升了1倍, 0.14 THz处输出功率增大了9.66倍, 互作用效率增大了3.22倍; 当增益相同时, 多注方式的互作用长度较单注缩短了33%. 该方法能够有效增大THz行波管的工作电流, 提高互作用增益及效率、3 dB带宽、输出功率; 在增益相同时, 基模多注行波管可以做得更短更紧凑.
    To improve the current and output power of the THz traveling wave tube (TWT), a fundamental mode multi-beam folded waveguide (FMMBFW) TWT scheme is proposed. Firstly, an equivalent circuit model FMMBFW for calculating the high-frequency characteristic is established and compared with numerical simulation. Secondly, the transmission characteristic of 60 periods FMMBFW is analyzed. Finally, the beam-wave interaction characteristic of 0.14 THz FMMBFW TWT is completed by numerical simulation and theoretical calculation. When the DC current is 12 mA and the applied voltage is 15.75 kV, the 3 dB bandwidth of 0.14 THz FMMBFW TWT is 25 GHz (128-153 GHz), the maximum gain is 33.61 dB and the maximum output power is 23 W. When the DC current is 30 mA and the voltage is 15.75 kV, the maximum gain is 38 dB and the maximum pulse output power is 63.1 W at 0.14 THz. Compared with the fundamental single-beam folded waveguide (FW) TWT under the same working condition, the 3 dB bandwidth is doubled, its output power is raised by a factor of 9.66 and the interaction efficiency is increased by 3.22 times. Based on the same gain, the length of FMMBFW TWT is just 52.6 mm while the length of single beam FW-TWT is 78.2 mm. The proposed method can increase effectively the current of FMMBFW TWT; and the interaction gain, efficiency, 3 dB bandwidth, output power can be improved. When the gain is the same, a shorted and compact FMMBFW TWT can be constucuted.
    • 基金项目: 中国工程物理研究院超精密加工技术重点实验室开放基金(批准号:2012CJMZZ00007)资助的课题.
    • Funds: Project supported by the Open Foundation of the Key Laboratory of Precision Manufacturing Technology of China Academy of Engineering Physics (Grant No. 2012CJMZZ00007).
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    Ha H J, Jung S S, Park G S 1998 Int. J. Infrared Millim. Waves 19 1229

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    Curnow H J 1965 IEEE Trans. Microw. Theory Tech. 13 671

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    Carter R G, Liu S K 1986 IEE Proc. H, Microw. Antenn. Propag. 133 330

    [25]

    Booske J H, Converse M C, Kory C L, Chevalier C T, Gallagher D A, Kreischer K E, Heinen V O, Bhattacharjee S 2005 IEEE Trans. Electron Dev. 52 685

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  • [1]

    Peter H S 2002 IEEE Trans. Microwave. Theory Tech. 50 910

    [2]

    John H B 2008 Phys. Plasmas 15 055502

    [3]

    Shin Y M, Larry R B, Neville C L 2009 IEEE Trans. Electron Dev. 56 3196

    [4]

    Shin Y M, Baig A, Larry R B, Tsai W C, Neville C L 2012 IEEE Trans. Electron Dev. 59 234

    [5]

    Baig A, Gamzina D, Barchfeld R, Domier C, Barnett L R, Neville C L 2012 Phys. Plasmas 19 093110

    [6]

    Field M, Griffith Z, Young A, Hillman C, Brar B 2014 15th IEEE International Vacuum Electronics Conference Monterey, USA, April 22-24, 2014 p225

    [7]

    Kory C L, Read M, Ives R L 2009 IEEE Trans. Electron Dev. 56 713

    [8]

    Comfoltey E N, Shapiro M, Sirigiri J, Temkin R 2009 10th IEEE International Vacuum Electronics Conference Rome, Italy, April 28-30, 2009 p127

    [9]

    Tucek J C, Basten M A, Gallagher D A, Kreischer K E 2010 11th IEEE International Vacuum Electronics Conference Monterey, USA, May 18-20, 2010 p19

    [10]

    Basten M A, Tucek J C, Gallagher D A 2009 10th IEEE International Vacuum Electronics Conference Rome, Italy, April 28-30, 2009 p110

    [11]

    Basten M A, Tucek J C, Gallagher D A, Kreischer K E 2013 14th IEEE International Vacuum Electronics Conference Paris, France, May 21-23, 2013 p1

    [12]

    Xu X, Wei Y Y, Shen F, Duan Z Y, Gong Y B, Yin H R, Wang W X 2011 IEEE Eletron. Dev. Lett. 32 1152

    [13]

    Lai J Q, Wei Y Y, Liu Y, Huang M Z, Tang T, Wang W X, Gong Y B 2012 Chin. Phys. B 21 068403

    [14]

    Liu L W, Wei Y Y, Wang S M, Hou Y, Yin H R, Zhao G Q, Duan Z Y, Xu J, Gong Y B, Wang W X, Yang M H 2013 Chin. Phys. B 22 108401

    [15]

    Hu Q 2012 Acta Phys. Sin. 61 014101 (in Chinese) [胡权 2012 物理学报 61 014101]

    [16]

    Lai J Q, Wei Y Y, Xu X, Shen F, Liu Y, Liu Y, Huang M Z, Tang T, Gong Y B 2012 Acta Phys. Sin. 61 178501 (in Chinese) [赖剑强, 魏彦玉, 许雄, 沈飞, 刘洋, 刘漾, 黄民智, 唐涛, 宫玉彬 2012 物理学报 61 178501]

    [17]

    Li S, Wang J G, Tong C J, Wang G Q, Lu X C, Wang X F 2013 Acta Phys. Sin. 62 120703 (in Chinese) [李爽, 王建国, 童长江, 王光强, 陆希成, 王雪锋 2013 物理学报 62 120703]

    [18]

    Feng J J, Cai J, Wu X P, Hu Y F, Cui Y D, Dong R T, Liu J K, Chen J, Zhang X Q 2014 15th IEEE International Vacuum Electronics Conference Monterey, USA, April 22-24, 2014 p173

    [19]

    Gong Y B, Yin H R, Yue L N, Lu Z G, Wei Y Y, Feng J J, Duan Z Y, Xu X 2011 IEEE Trans. Plasma Sci. 39 847

    [20]

    Wang S J, Xue X Z, Wang Z C, Zhang S C, Guo J 2014 Chin. J. Vacuum Sci. Technol. 34 43 (in Chinese) [王书见, 薛谦忠, 王自成, 张世昌, 郭际2014真空科学与技术学报 34 43]

    [21]

    Dohler G, Gagne D, Gallagher D, Moats R 1987 IEDM Tech. Dig. 33 485

    [22]

    Ha H J, Jung S S, Park G S 1998 Int. J. Infrared Millim. Waves 19 1229

    [23]

    Curnow H J 1965 IEEE Trans. Microw. Theory Tech. 13 671

    [24]

    Carter R G, Liu S K 1986 IEE Proc. H, Microw. Antenn. Propag. 133 330

    [25]

    Booske J H, Converse M C, Kory C L, Chevalier C T, Gallagher D A, Kreischer K E, Heinen V O, Bhattacharjee S 2005 IEEE Trans. Electron Dev. 52 685

    [26]

    Marcuvitz L 1986 Waveguide Handbook (London: Peter Peregrinus) p365

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出版历程
  • 收稿日期:  2014-07-04
  • 修回日期:  2014-07-20
  • 刊出日期:  2014-12-05

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