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Linear theory of beam–wave interaction in double-slot coupled cavity travelling wave tube 被引量:1

Linear theory of beam–wave interaction in double-slot coupled cavity travelling wave tube
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摘要 A three-dimensional model of the double-slot coupled cavity slow-wave structure (CCSWS) with a solid round elec- tron beam for the beam-wave interaction is presented. Based on the "cold" dispersion, the "hot" dispersion equation is derived with the Maxwell equations by using the variable separation method and the field-matching method. Through numerical calculations, the effects of the electron beam parameters and the staggered angle between adjacent walls on the linear gain are analyzed. A three-dimensional model of the double-slot coupled cavity slow-wave structure (CCSWS) with a solid round elec- tron beam for the beam-wave interaction is presented. Based on the "cold" dispersion, the "hot" dispersion equation is derived with the Maxwell equations by using the variable separation method and the field-matching method. Through numerical calculations, the effects of the electron beam parameters and the staggered angle between adjacent walls on the linear gain are analyzed.
作者 何昉明 谢文球 罗积润 朱敏 郭炜
机构地区 Radar Research (Beijing) Aviation Key Laboratory of Science and Technology on AISSS Institute of Electronics University of Chinese Academy of Sciences
出处 《Chinese Physics B》 SCIE EI CAS CSCD 2016年第3期424-427,共4页 中国物理B(英文版)
基金 Project supported by the National Natural Science Foundation of China(Grant No.11205162)
关键词 double-slot coupled cavity slow-wave structure beam-wave interaction field matching method small signal gain double-slot coupled cavity slow-wave structure, beam-wave interaction, field matching method,small signal gain
分类号 TN124 [电子电信—物理电子学]
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参考文献10

  • 1Cusick M, Begum R, Gajaria D, Grant T, Kolda P, Legarra J, Meyer C, Ramirez-Aldana J L, Pedro D S, Stockwell B and Yamane G 2012 13th IEEE International Vacuum Electronics Conference (IVEC 2012), April 24-26, 2012, Monterey, USA, p. 227.
  • 2Wang B and Xie W K 2007 Acta Phys. Sin 56 567138 (in Chinese).
  • 3Freund H P, Thomas M, Antonsen J, Zaidman E G, Levush B and Legarra J 2002 IEEE Trans. Plasma Science 30 1024.
  • 4Chernin D, Thomas M, Antonsen J, Chernyavskiy I A, Vlasov A N, Levush B, Begum R and Legarra J R 2011 IEEE Trans. Electron Devices 58 1229.
  • 5Bai C J, Li J, Q Hu Y L, Yang Z H and Li B 2012 Acta Phys. Sin 61 178401 (in Chinese).
  • 6He F M, Luo J R, Zhu M and Guo W 2013 IEEE Trans. Electron Devices 60 774.
  • 7Freund H P, Kodis M A and Vanderplaats N R 1992 IEEE Trans. Plasma Science 20 543.
  • 8Liu Y, Xu J, Lai J Q, Xu X, Shen F, Wei Y Y, Huang M Z, Tang T and Gong Y B 2012 Chin. Phys. B 21 074202.
  • 9Lawson J D 1988 The Physics of Charged Particles (Oxford: Clarendon Press) p. 293.
  • 10Gilmour A S 2011 Principles of Klystrons, Traveling Wave Tubes, Magnetrons, Crossed-Field Amplifiers and Gyrotrons (Norwood: Artech House) p. 422.

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引证文献1

Chinese Physics B
2016年 第3期

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