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One of the problems encountered in the design of high-power gyrotrons is the need to ensure stable single-mode generation. The conditions of spurious self-excitation in a gyrotron resonator have been studied fairly completely, and methods for its suppression have been developed (see Petelin [1] and Nusionvich [2], for example). At the same time, stable gyrotron operation can also be disrupted by the generation of spurious oscillations in the transition region between the electron gun and the resonator, where the electromagnetic field is nonuniform. A theoretical basis for this assumption is provided by results [1, 3, 4] indicating a fairly high efficiency of interaction of a high-frequency field with an electron current guided by a nonuniform magnetostatic field.Institute of Applied Physics, Russian Academy of Sciences. Translated from Izvestiya Vysshikh Uchebnykh Zavedenii, Radiofizika, Vol. 37, No. 11, pp. 1458–1472, November, 1994. 相似文献
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Samsonov S. V. Bogdashov A. A. Gachev I. G. Denisov G. G. 《Radiophysics and Quantum Electronics》2019,62(7-8):455-466
Radiophysics and Quantum Electronics - The gyrotron traveling-wave tube (gyro-TWT) is a wideband version of gyrotron amplifiers, which produce pulsed or continuous-wave radiation in the... 相似文献
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Zasypkin E. V. Gachev I. G. Sokolov E.V. Antakov I. I. 《Radiophysics and Quantum Electronics》2021,64(7):482-493
Radiophysics and Quantum Electronics - We have developed and studied experimentally a two-cavity gyroklystron operating at a frequency of 35 GHz and the cavity mode TE0 2 1 in a cryomagnet. The... 相似文献
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We have developed and tested a gyroklystron operating with the second harmonic of the electron cyclotron frequency at a frequency
of 32.3 GHz in the field of a permanent magnet. In the two-and three-cavity versions of the gyroklystron, the peak power of
the output radiation reached 320 kW with an efficiency of 30%, an amplification coefficient of 20–25 dB, and an operating
frequency bandwidth of 0.05%. In the wide-band version of the gyroklystron, the amplification bandwidth was equal to 0.27%
for an output power of 200 kW and an amplification coefficient of 13 dB. 相似文献
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Rozental’ R. M. Bogdashov A. A. Gachev I. G. Samsonov S. V. 《Radiophysics and Quantum Electronics》2022,65(3):183-195
Radiophysics and Quantum Electronics - We present the results of studying experimentally gyroresonance K-band traveling-wave tubes having kilowatt power levels in the output radiation, in which the... 相似文献
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Zasypkin E.V. Moiseev M.A. Gachev I.G. Antakov I.I. 《IEEE transactions on plasma science. IEEE Nuclear and Plasma Sciences Society》1996,24(3):666-670
The self-consistent nonlinear theory of two-cavity high-harmonic gyroklystron amplifier has been developed. The efficiency and gain of a second-harmonic gyroklystron were calculated numerically. The results obtained were used to choose the optimal parameters of the experimental second-harmonic tube. The experimental study was carried out to test high-harmonic amplifier concept. Two-cavity 35 GHz second harmonic gyroklystron with the TE021 cavity mode has been designed and tested in pulse operation. Output power of about 260 kW with efficiency 18% and 17 dB gain have been produced at 72 kV beam voltage and 20 A beam current. Bandwidth of about 0.1% has been observed. The restriction of the output power, efficiency, and gain was caused by spurious oscillations excited in the second cavity in the TE011 mode at the fundamental cyclotron frequency 相似文献
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