W波段四腔回旋速调管放大器

介绍了W波段四腔回旋速调管放大器的设计.放大器工作在基膜TE01圆电模式，电子束工作电压70 kV，工作电流6 A，设计的双阳极磁控式注入电子枪，电子束纵横速度比1.5，速度零散小于4%.采用粒子模拟方法分析了各种参数对器件性能的影响.模拟结果显示，设计的放大器在电子束速度零散4%的情况下，增益35 dB，带宽800 MHz，输出功率100 kW，效率为23.8%.

Abstract

The design of a W-band four-cavity gyroklystron amplifier is presented. The device operates in the fundamental harmonic TE01 circular electric mode. The 70 kV, 6 A beam is produced by a double anode magnetron injection gun (MIG) with an average perpendicular-to-parallel velocity ratio of 1.5 and a parallel velocity spread of less than 4%. Particle-in-cell (PIC) simulations have been performed to predict general RF performance for various parameters. The simulated results show that the designed gyroklystron amplifier can produce about 35 dB gain, 800 MHz bandwidth and 100 kW peak output power with power conversion efficiency of 23.8% for a beam with 4% axial velocity spread.

参考文献

[1] Barker R J ,Schamiloglu E. High-Power Microwave Sources and Technologies[M]. Piscataway, NJ: IEEE, 2001.

[2] Felch K L, Danly B G, Jory H R, et al. Characteristics and applications of fast-wave gyrodevices[J]. Proc. IEEE, 1999, 87(5): 752781.

[3] Granatstein V L, Baruch Levush, Danly B G. et al. A quarter century of gyrotron research and development[J]. IEEE Trans. Plasma Sci., 1997, 25(6):13221335.

[4] Chu K R. The electron cyclotron maser[J]. Rev. Modern Phys. 2004, 76(2), 489540.

[5] Thumm M. State-of-the-art of high power gyro-devices and free electron masers update 2011, KIT Scientific Reports 7606 [EB OL]. http://uvka.ubka.uni-karlsruhe.de/shop/download.

[6] Antokov I I, Zasypkin E V, Sokolov E V. 35GHz radar gyroklystron [C]. in Proc. 18th Int. Conf. IR&MM Waves, UK, 1993:338339.

[7] Gachev I G, Antakov I I, Lygin V K, et al. A ka-band second-harmonic gyroklystron with permanent magnet[C]. Fifth International Workshop Strong Microwaves in Plasmas, Russia, 2002.

[8] Tolkachev A A, Solovjev B A, Solovjev G K. et al. A megawatt power millimeter-wave phase-array radar[J]. IEEE AES Systems Magazine, 2000,7: 2531.

[9] Choi J J, McCurdy A H, Wood F N ,et al. Experimental investigation of a high power, two-cavity, 35GHz gyroklystron amplifier[J]. IEEE Trans. Plasma Sci., 1998, 26(3): 416425.

[10] Calame J P, Garven M, Choi J J ,et al. Experimental studies of bandwith and power production in a three-cavity, 35GHz gyroklystron amplifier[J]. Phys. Plasma, 1999, 6(1): 285297.

[11] Ngo M, Danly B G, Myers R, et al. High-power millimeter-wave transmitter for the NRL WARLOC radar[C]. IVEC2002, USA: Monterey, 2002: 363364.

[12] Blank M, Danly B G, Levush B, et. al. Demonstration of a 10 kW average power 94 GHz gyroklystron amplifier[J]. Physics of plasmas, 1999,6(12): 44054409.

[13] Granatstein V L, Lawson W. Gyro-amplifiers as candidate RF drivers for TeV linear colliders[J]. IEEE Trans. Plasma Sci., 1996, 24(3): 648665.

[14] Lawson W, Cheng J, Calame J P, et al. High power operation of a three-cavity X-band coaxial gyroklystron[J]. Phys. Rev.Lett., 1998, 81, 30303033.

[15] Liu Pu-Kun, Zhang Shi.-Chang, Xu Shou-Xi, et al. Experimental studies of a ka-band second harmonic gyroklystron[C]. IRMMW-THz2010, Italy: Rome, 2010:

[16] DI Jun，ZHU Da-Jun，LIU Sheng-Gang, Electromagnetic field algorithms of CHIPIC Code[J]. Journal of UEST of China, 2005, 34(4),485488.

[17] Liu Pu-Kun, Zhang Shi-Chang, Xu Shou-Xi, et al, Recent results in the development of a ka-band second harmonic gyroklystron amplifier [C]. IVEC2007, Japan, 2007, 237238.

[18] Heinrich FLGEL ,Eberhard KHN, Computer-aided analysis and design of circular waveguide tapers[J]. IEEE Trans. On MTT, 1988, 36(2), 332336.

徐寿喜, 刘濮鲲, 张世昌, 薛谦忠, 杜朝海, 耿志辉, 粟亦农, 刘高峰, 史少辉. W波段四腔回旋速调管放大器[J]. 红外与毫米波学报, 2013, 32(3): 205. XU Shou-Xi, LIU Pu-Kun, ZHANG Shi-Chang, XUE Qian-Zhong, DU Chao-Hai, GENG Zhi-Hui, SU Yi-Nong, LIU Gao-Feng, SHI Shao-Hui. A W-band four-cavity gyroklystron amplifier[J]. Journal of Infrared and Millimeter Waves, 2013, 32(3): 205.

W波段四腔回旋速调管放大器

关于本站 Cookie 的使用提示

全站搜索

W波段四腔回旋速调管放大器

相关论文

相关资讯

关于本站 Cookie 的使用提示

全站搜索