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

For citation:

Khutoryan E. M., Ponomarenko S. S., Kishko S. A., Lukin K. A., Kuleshov A. N., Efimov B. P. Autooscillations in o-type oscillator at excitation of space-surface mode in resonator with a periodically inhomogeneous grating. Izvestiya VUZ. Applied Nonlinear Dynamics, 2013, vol. 21, iss. 2, pp. 9-19. DOI: 10.18500/0869-6632-2013-21-2-9-19

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Language: 
Russian
Heading: 
Applied Problems of Nonlinear Oscillation and Wave Theory
Article type: 
Article
UDC: 
621.385.6
DOI: 
10.18500/0869-6632-2013-21-2-9-19

Autooscillations in o-type oscillator at excitation of space-surface mode in resonator with a periodically inhomogeneous grating

Autors: 
Khutoryan Eduard Mihajlovich, A.Ya. Usikov Institute for Radiophysics and Electronics National Academy of Sciences of Ukraine
Ponomarenko Sergej Stanislavovich, A.Ya. Usikov Institute for Radiophysics and Electronics National Academy of Sciences of Ukraine
Kishko Sergej Aleksandrovich, A.Ya. Usikov Institute for Radiophysics and Electronics National Academy of Sciences of Ukraine
Lukin Konstantin Aleksandrovich, A.Ya. Usikov Institute for Radiophysics and Electronics National Academy of Sciences of Ukraine
Kuleshov Aleksej Nikolaevich, A.Ya. Usikov Institute for Radiophysics and Electronics National Academy of Sciences of Ukraine
Efimov Boris Petrovich, A.Ya. Usikov Institute for Radiophysics and Electronics National Academy of Sciences of Ukraine
Abstract: 

The regime of the simultaneous existence of space and surface waves in the O-type oscillator with a periodically inhomogeneous comb has been considered. The impedance and quality factor dependences for space waves, surface waves and hybrid mode have been compared.

Key words: 
backward wave oscillator
clinotron
electron beam
ledatron
inhomogeneous grating
surface waves
space waves
Reference: 
  1. Yun-Shik Lee. Principles of Terahertz Science and Technology. New-York: Springer; 2009. 340 p.
  2. Shevchik VN, Trubetskov DI. Inverse wave lamp electronics. Saratov: Saratov University Publishing; 1975. 194 p.
  3. Mineo M, Paoloni C. Double corrugation rectangular waveguide slow-wave structure for THz vacuum devices. IEEE Trans. Electron Devices. 2010;57(11):3169–3175. DOI:10.1109/TED.2010.2071876
  4. Levush B, Antonsen TM, Bromborsky A, Lou WR, Carmel Y. Theory of relativistic backward-wave oscillators with end reflectors. IEEE on Plasma Science. 1992;20(3):263–280. DOI:10.1109/27.142828
  5. Nusinovich GS, Bliokh YuP. Mode interaction in backward-wave oscillators with strong end reflections. Physics of Plasmas. 2000;7(4):1294–1301. DOI: 10.1063/1.873940
  6. Efimov BP, Lukin KA, Rakityanskiy VA. Transformation of chaotic oscillation spectrum by reflection. J. of Tech. Physics. 1988;58(12):2398–2398.
  7. Levin GYa, Borodkin AI, Kirichenko AYa. at al. Klinotron. Ed. Usikov AYa. Kiev: Naukova Dumka; 1992. 200 p. (In Russian).
  8. Schunemann K, Vavriv DM. Theory of the clinotron: A grating backward-wave oscillator with inclined electron beam. IEEE Trans. Electron Devices. 1999; 46(11):2245–2252. DOI:10.1109/16.796302
  9. Milcho MV, Yefimov BP, Zavertanniy VV, Goncharov VV. Peculiar features of klynotron-type oscillator performances. Radiofizika i elektronika. Kharkov: IRE NAS of Ukraine Publ. 2005;10(3):435–440. (in Russian).
  10. Lysenko EE, Pishko OF, Chumak VG, Churilova SA. Resonance Line Q-Factor of Millimeter-Wave Clinotron. RADIO PHYSICS AND RADIO ASTRONOMY. 2001;6(4):317-322.
  11. Zavertannyj VV, Kishko SA, Ponomarenko SS, Efimov BP, Zabrodskij AF, Kirichenko LA, Kudinova TV, Kuleshov AN. Magnetic focusing system for intense electron beams of submillimeter clinotrons. Izvestiya VUZ. Applied Nonlinear Dynamics. 2012;20(5):112-120. DOI: 10.18500/0869-6632-2012-20-5-112-120.
  12. Shestopalov VP, Vertiy AA, Ermak GP. at al. Diffraction radiation generators. Kiev: Naukova Dumka; 1991. 317 p. (In Russian).
  13. Bratman VL, Dumesh BS, Fedotov AE, Grishin YuA, Rusin FS. Broadband orotron operation at millimeter and submillimeter waves. International Journal of Infrared and Millimeter Waves. 2002;23(11):1595–1601. DOI:10.1023/A:1020749601248
  14. Lysenko EE, Pishko OF, Churilova SA. Experimental Research of Clinotron with Distributed Quasioptical Power Output. RADIO PHYSICS AND RADIO ASTRONOMY. 1999;4(1):13–20.
  15. Kravchenko VF, Suk AF. Diffraction properties of multi-element periodic structures of metal perfectly conductive bars. Dokl. Akad. Nauk. 1974;А(10):3.
  16. Shestopalov VP, Sirenko JK. Dynamic lattice theory. Kiev: Naukova Dumka; 1989. 216 p.
  17. Kolmakova NG, Perov AO, Senkevich SL, Kirilenko AA. Abnormal propagation of EMW through below cutoff holes and intrinsic oscillations of waveguide objects and periodic structures. Radioelectronics and Communications Systems. 2011;54(3):115-123. DOI 10.3103/S0735272711030010.
  18. Shestopalov VP, Litvinenko LN, Masalov SA, Sologub VG. Diffraction of waves on gratings. Kharkov: Kharkiv University Publ., 1973. 288 p.
  19. Kuznetsov AP, Kuznetsov SP. Nonlinear non-stationary equations of electron flux interaction with electromagnetic fields near the boundary of the Brillouin zone. Radiophysics and Quantum Electronics. 1984;27(12):1575–1583.
  20. Trubetskov DI, Hramov AE. Lectures on ultra-high frequency electronics for physicists. V. 1. Moscow: Fizmatlit; 2003. 496 p. (In Russian).
Received: 
12.08.2012
Accepted: 
01.04.2013
Published: 
31.07.2013
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