32 GHZ СOLD CATHODE MAGNETRON WITH SPAСE HARMONICS – NONLINEAR ANALYTICAL CALCULATION AND 3D-SIMULATION

Cite this article as:

Yeryomka V. D., Kopot М. А., Kulagin O. P. 32 GHZ СOLD CATHODE MAGNETRON WITH SPAСE HARMONICS – NONLINEAR ANALYTICAL CALCULATION AND 3D-SIMULATION. Izvestiya VUZ. Applied Nonlinear Dynamics, 2014, vol. 22, iss. 3, pp. 53-62. DOI: https://doi.org/10.18500/0869-6632-2014-22-3-53-62

The analytical estimation of the optimal parameters fulfilled for pulsed magnetrons with cold secondary-emission cathodes, operating at a frequency of 32 GHz with anode voltage of 8 kV and with magnetic field of about 0.4 Tesla. As shown, the geometry of the magnetron interaction space can ensure an interaction between electrons and the high-frequency field as for the (−1)-th space harmonic of π/2-oscillations, so for (+1)- th space harmonic π-oscillations in the drift-orbit resonance mode. Three-dimensional numerical experiments show that both modifications of the tube can provide the required power characteristics. The possibility to use the chosen non-linear analytical model for preliminary calculations of the operating parameters of the non-classical M- type spatia-lharmonics tubes is confirmed.

Authors:

Yeryomka Victor Danilovich, O.Ya. Usikov Institute for Radiophysics and Electronics of the National Academy of Science of Ukraine, ul. Akademika Proskury, 12, Kharkiv, 61085, Ukraine , v.yeryomka@gmail.com

Kopot М. А., Харьковский национальный университет радиоэлектроники, Общий юридический адрес: Украина, Харьков, 61166, пр. Ленина, 14 Телефон/факс: +38 (057) 702-10-13 , miko_ua@list.ru

Kulagin O. P., O.Ya. Usikov Institute for Radiophysics and Electronics of the National Academy of Science of Ukraine, ul. Akademika Proskury, 12, Kharkiv, 61085, Ukraine , kulagin2008@mail.ru

Key words:

Drift-orbital resonance, spatial harmonics magnetrons, three-dimensional numerical model, non-linear analytical model.

DOI:

10.18500/0869-6632-2014-22-3-53-62

Literature

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6. Avtomonov N.I., Sosnytskiy S.V., Vavriv D.M. Dependence of magnetron characteristics on the secondary-emission yield of cold cathode // Вопросы атомной науки и техники. Серия: Плазменная электроника и новые методы ускорения (5). 2006. No 5. C. 225.

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10. Yeryomka V.D., Kopot’ M.A., Kulagin O.P., Tishchenko A.S., Naumenko V.D., Suvorov A.N., Jung-Il Kim. Simulation and experimental breadboarding of 35 GHz spatial harmonic magnetrons with cold cathode // 20-я Международная Крымская конф. «СВЧ-техника и телекоммуникационные технологии» (КрыМиКо’2010), Украина, 2010, Труды конф. Т. 1. С. 310.

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Journal issue:

«Izvestiya VUZ. AND», 2014, т. 22, №3,

Heading:

Innovations in Applied Physics

Status:

одобрено к публикации

Short Text (PDF):

a2014no3p053.doc_.pdf

Full Text (PDF):

eremka_3_2014.pdf

BibTeX

@article{Ерёмка-IzvVUZ_AND-22-3-53,
author = {Victor Danilovich Yeryomka and М. А. Kopot and O. P. Kulagin},
title = {32 GHZ СOLD CATHODE MAGNETRON WITH SPAСE HARMONICS – NONLINEAR ANALYTICAL CALCULATION AND 3D-SIMULATION},
year = {2014},
journal = {Izvestiya VUZ. Applied Nonlinear Dynamics},
volume = {22},number = {3},
url = {https://old-andjournal.sgu.ru/en/articles/32-ghz-sold-cathode-magnetron-with-spase-harmonics-nonlinear-analytical-calculation-and-3d},
address = {Саратов},
language = {russian},
doi = {10.18500/0869-6632-2014-22-3-53-62},pages = {53--62},issn = {0869-6632},
keywords = {Drift-orbital resonance,spatial harmonics magnetrons,three-dimensional numerical model,non-linear analytical model.},
abstract = {The analytical estimation of the optimal parameters fulfilled for pulsed magnetrons with cold secondary-emission cathodes, operating at a frequency of 32 GHz with anode voltage of 8 kV and with magnetic field of about 0.4 Tesla. As shown, the geometry of the magnetron interaction space can ensure an interaction between electrons and the high-frequency field as for the (−1)-th space harmonic of π/2-oscillations, so for (+1)- th space harmonic π-oscillations in the drift-orbit resonance mode. Three-dimensional numerical experiments show that both modifications of the tube can provide the required power characteristics. The possibility to use the chosen non-linear analytical model for preliminary calculations of the operating parameters of the non-classical M- type spatia-lharmonics tubes is confirmed. }}