ISSN 0869-6632 (Print)
ISSN 2542-1905 (Online)


For citation:

Bezgina I. P., Yeryomka V. D., Makulina T. A., Mytsenko I. M. Current-less tuning and control of self-oscillations frequency terahertz range klynotron. Izvestiya VUZ. Applied Nonlinear Dynamics, 2015, vol. 23, iss. 6, pp. 47-59. DOI: 10.18500/0869-6632-2015-23-6-47-59

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Language: 
Russian
Article type: 
Article
UDC: 
621.385.6

Current-less tuning and control of self-oscillations frequency terahertz range klynotron

Autors: 
Bezgina Irina Petrovna, A.Ya. Usikov Institute for Radiophysics and Electronics National Academy of Sciences of Ukraine
Yeryomka Viktor Danilovich, A.Ya. Usikov Institute for Radiophysics and Electronics National Academy of Sciences of Ukraine
Makulina Tatjana Alekseevna, A.Ya. Usikov Institute for Radiophysics and Electronics National Academy of Sciences of Ukraine
Mytsenko Igor Mihajlovich, A.Ya. Usikov Institute for Radiophysics and Electronics National Academy of Sciences of Ukraine
Abstract: 

Terahertz-range backward wave oscillator – carcinotrons and klynotrons are widely used in radioelectronics systems for solving fundamental and applied problems. Instability of the output signal frequency of the said lamps is not worse than 10?4. The frequency of the carcinotron and klynotron output signal as a rule carried out by changing the operating voltage, i.e. with the expenditure of energy in the control circuit. In this paper, we report on the design of the terahertz electromagnetic radiation klуnotron oscillator, which provides an implementation method current-less tunning and stabilization frequency of its output signal Based on the results of studies concluded that the possibility of the process of restructuring oscillation frequency terahertz range klynotron oscillator, which, unlike traditional methods, does not lead to an increase in the emission spectrum of additional spectral components and allows for tuning of the frequency of self-oscillations in the range of hundreds of MHz – GHz units, provide stability close to the stability of the oscillation frequency of the reference resonator.

Reference: 
  1. Neumann M.S. Frequency Stabilization in Radio. Svyaz’izdat. 1937. 157 p. (in Russian).
  2. Groszkowski Ya. Generation of High-Frequency Oscillations and Frequency Stabilization. M.: Foreign Literature, 1953. 364 p. (in Russian).
  3. Bychkov S.I., Burenin N.I., Safarov R.T. Frequency Stabilization of Microwave Oscillators. M.: Soviet Radio, 1962 . 376 p. (in Russian).
  4. Kovshov Y.S., Ivanov A.I., Kishko S.A., Ponomarenko S.S., Kuleshov A.N., Yephimov B.P. Stabilization of the electromagnetic oscillations frequency in the submillimeter range BWT oscillators // News of the V.N. Karazin Kharkiv National University. 2013. No1094. Ser. «Radiophysics and electronics», Issue 23. P. 77 (in Russian).
  5. Authorship Certificate No341113 from 12.17.1956 USSR. Backward Wave Tube / G.Ya. Levin (USSR) // Bull. Discoveries and Inventions. 1972. No 25. P. 201 (In Russian).
  6. Klynotron / G.Ya.Levin. A.I.Borodkin, A.Ya.Kirichenko et al., Ed. A.Ya.Usikov. Kiev: Naukova Dumka, 1992. 200 p. (in Russian).
  7. Kirichenko A.Y., Yakovenko V.M. Klynotron – 50 // Radio Physics and Electronics. Collection of Scientific Papers / NAS of Ukraine. A.Ya. Usikov Institute of Radiophysics and Electronics. Kharkiv, 2007. Vol.12, Special Issue. P.5 (in Russian).
  8. Yeryomka V.D. Terahertz vacuum electromagnetic radiation sources: Evolution zig-zag from klynotron to klynoorbictron // Izv. VUZ. Applied Nonlinear Dynamics. 2013. Vol. 21, No 1. P. 7 (in Russian).
  9. Altshuler Yu.G., Tatarenko A.S. Tubes with Low-Power Backward Wave. M.: Sov. Radio, 1963. 296 p. (in Russian).
  10. Authorship Certificate No555751 from 8.01.1976 USSR, ICI H01 J 25/00. Backward wave tube / V.D. Yeryomka, A.Ya.Kirichenko, V.A.Solodovnik (USSR) // Bull. Discoveries and Inventions. 1979. No 10. P. 189 (in Russian).
  11. Silin R.A., Sazonov V.P. Slow Wave Systems. M.: Sov. Radio, 1966. 632 p. (in Russian).
  12. Yeryomka V.D., Kirichenko A.Ya., Solodovnik V.A. Study the possibility of current-free frequency control O-type BWO-klynotron // Proceedings of the Institute of Radio Physics and Electronics AS of Ukrainian SSR. 1977. Vol. 23. P. 60 (in Russian).
  13. Authorship Certificate No892741 from 29.10.1979 USSR, ICI H03 L 7/06. The Device Oscillator Frequency Stabilization / I.M. Balaklitsky, Yu.V. Maystrenko, I.M. Mytsenko (USSR) // Bull. Discoveries and Inventions. 1981. No 47. Р. 171 (in Russian).
  14. Mytsenko I.M., Roenko A.N., Chernyavsky I.Y. Device for stabilizing the frequency of the microwave oscillator // Collection of scientific works of the Kharkov Military University. Kharkiv, 2002. Issue 3 (41). P. 108 (in Russian).
  15. Gonorovsky I.S. Radio Circuits and Signals. M.: Soviet Radio, 1971. 672 p. (in Russian).
  16. Semenov A.N. Technical Electrodynamics. M.: Svyaz’, 1973. 480 p. (in Russian).
Received: 
25.06.2015
Accepted: 
25.06.2015
Published: 
29.04.2016
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