Analysis of the Gyro-Back Wave Oscillations of the TE21 Mode

Zhang Tao; Jiao Chong-qing; Luo Ji-run

doi:10.3724/SP.J.1146.2008.00233

Volume 32 Issue 2

Aug. 2010

Turn off MathJax

Article Contents

Article Navigation > Journal of Electronics & Information Technology > 2010 > 32(2): 459-463

Zhang Tao, Jiao Chong-qing, Luo Ji-run. Analysis of the Gyro-Back Wave Oscillations of the TE21 Mode[J]. Journal of Electronics & Information Technology, 2010, 32(2): 459-463. doi: 10.3724/SP.J.1146.2008.00233

Citation:

Zhang Tao, Jiao Chong-qing, Luo Ji-run. Analysis of the Gyro-Back Wave Oscillations of the TE21 Mode[J]. Journal of Electronics & Information Technology, 2010, 32(2): 459-463. doi: 10.3724/SP.J.1146.2008.00233

Citation:

PDF( 270 KB)

Analysis of the Gyro-Back Wave Oscillations of the TE21 Mode

doi: 10.3724/SP.J.1146.2008.00233

Received Date: 2008-03-06
Rev Recd Date: 2009-11-16
Publish Date: 2010-02-19

Abstract

Abstract

Based on the linear theory of gyro-TWA, this paper is focused on the numerical simulations for the relations of the starting length and starting frequency with beam radius, voltage, velocity ratio, beam current and magnetic field for a gyro-BWO operating in the TE21 mode at fundamental or second harmonic and the corresponding physical mechanisms is explained. And the effect of distributed wall losses on the suppression of the TE21 mode gyro-BWO is discussed. The results in this paper are helpful for the design of gyro-TWA and gyro-BWOs.

FullText(HTML)

References(1)

References

Chu K R. Overview of research on the gyrotron traveling-wave amplifier[J].IEEE Transactions on Plasma Science.2002, 30(3):903-908[2]Chu K R. The electron cyclotron maser, Reviews Modern Physics, 2004, 76(2): 489-540.[3]Jiao Chong-qing and Luo Ji-run. Linear theory of the electron cyclotron maser based on the TM circular waveguide mode[J].Physics Plasmas.2006, 13(7):073104-073108[4]Kou C S, Wang Q S, and McDermott D B, et al.. High-power harmonic gyro-TWTspart I: linear theory and oscillation study[J].IEEE Transactions on Plasma Science.1992, 20(3):155-162[5]Jiao Chong-qing and Luo Ji-run. Linear and nonlinear analysis of a gyrotron traveling wave amplifier with misaligned electron beam[J].Physics Plasmas.2006, 13(11):113101-113107[6]Zhang Shi-chang. Linear and nonlinear investigation of a coaxial-waveguide cyclotron autoresonance maser amplifier[J].Physics Plasmas.2004, 11(8):3969-3975[7]Zhang Shi-chang and Thumm M. Gyrokinetic description of the structural eccentricity influence on the starting current of a coaxial-cavity gyrotron[J].Physics Plasma.1999, 6(5):1622-1626[8]焦重庆, 罗积润. 有损金属圆波导中电磁波传输特性的研究. 物理学报, 2006, 55(12): 6360-6367.[9]Jiao Chong-qing and Luo Ji-run. Propagation of[10]electromagnetic wave in a lossy cylindrical waveguide. Acta[11]Physica Sinica, 2006, 55(12): 6360-6367.[12]Luo Ji-run and Jiao Chong-qing. Effect of the lossy layer thickness of metal cylindrical waveguide wall on the propagation constant of electromagnetic modes[J].Application Physics Letters.2006, 88(6):061115-061117[13]Chu K R and Lin A T. Gain and bandwidth of the gyro-TWT and CARM amplifiers[J].IEEE Transactions on Plasma Science.1988, 16(2):90-104[14]Kou C S. Starting oscillation conditions for gyrotron backward oscillators[J].Physics Plasmas.1994, 1(9):3093-3099[15]Chang T H and Chen S H. Stepwise frequency tuning of a gyrotron backward-wave oscillator[J].Physics Plasmas.2005, 12(1):013104-013108[16]Chu K R, et al.. Theory and experiment of ultrahigh gain gyrotron traveling wave amplifier[J].IEEE Transactions on Plasma Science.1999, 27(2):391-404[17]Nguyen K T, et al.. Design of Ka-band gyro-TWT for radar applications[J].IEEE Transactions on Electron Development.2001, 48(1):108-115

Relative Articles

Supplements(0)

Cited By

Proportional views