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Telecommunications and Radio Engineering
SJR: 0.202 SNIP: 0.2 CiteScore™: 0.23

ISSN Печать: 0040-2508
ISSN Онлайн: 1943-6009

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Telecommunications and Radio Engineering

DOI: 10.1615/TelecomRadEng.v70.i16.30
pages 1439-1447


G. A. Alexeev
A. Usikov Institute of Radio Physics and Electronics, National Academy of Sciences of Ukraine
L. V. Stulova
A. Usikov Institute of Radio Physics and Electronics, National Academy of Sciences of Ukraine, 12, Academician Proskura St., Kharkov 61085, Ukraine

Краткое описание

Distributed (relay-race) interaction between the wide strip electron beam and the traveling space field harmonic in the presence of the transverse static magnetic field in the drift space is studied theoretically. Designing of microwave devices of traveling wave klystron type is analyzed. These devices use spatial (distributed) modulation of the electron velocity followed by the electron dynamic focusing in the drift space.


  1. Alexeev, G.A., Kirichenko, A.Ya., and Mikhailov, V.I., The aspects of designing of microwave oscillation sources with relay-race interaction.

  2. Alexeev, G.A. and Mikhailov, V.I., On some opportunities for using of relay-race interaction of electron beams for development of mm- and submm-wave sources.

  3. Alexeev, G.A., Kirichenko, A.Ya., and Mikhailov, V.I., On the mechanism of bunching of the electron wave in the traveling-wave klystron in the presence of transverse magnetic field.

  4. Mihran, T.G., The Duplex Traveling-Wave Clystron.

  5. Pohl, W.J., The Design and Demonstration of a Wide-Band Multiple-Beam Traveling-Wave Clystron.

  6. Lau, Y.Y., Collective-Interaction Klystron.

  7. Lau, Y.Y., Patent Number: 4,617,493 Collective-Interaction Klystron.

  8. Andrushkevich, V.S., Vyrsky, V.A., Gamayunov, Yu.G., and Shevchik, V.N., Amplifying clystrons with distributed interaction.

  9. Shevchik, V.N., Basics of microwave electronics.

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