一种基于油介质开关振荡器的紧凑宽带高功率微波源
[1] Prather W D, Baum C E, Torres R J, et al. Survey of worldwide high-power wideband capabilities[J]. IEEE Trans Electromagnetic Compatibility, 2004, 46(3): 335-344.
[2] Baum C E. Switched oscillators[R]. Circuit and Electromagnetic System Design Notes, Note 45, 2000.
[3] Baum C E. The dispatcher: A new mesoband, high-power radiator[C]//Proc URSI General Assembly. 2002.
[4] Burger J, Baum C E, Prather W D, et al. Modular low frequency high power microwave generator[C]//Proc AMEREM. 2002.
[5] Giri D V, Tesche F M, Abdalla M D, et al. Switched oscillators and their integration into helical antennas[J]. IEEE Trans Plasma Science, 2010, 38(6): 1411-1426.
[6] Vega F, Rachidi F, Mora N, et al. Design and optimization of mesoband radiators using chain parameters[C]//IEEE International Conference on Electromagnetics in Advanced Applications (ICEAA). 2011: 1310-1313.
[7] Ryu J, Yim D, Lee J. Analysis and design of switched transmission line circuits for high-power wide-band radiation[J]. Journal of the Korean Physical Society, 2011, 59(61): 3567-3572.
[8] Armanious M M, Tyo J S, Skipper M C, et al. Generation and radiation of high-power mesoband waveforms using quarter-wave switched oscillators[C]//Proc of 30th URSI General Assembly and Scientific Symposium. 2011: 1-4.
[9] Armanious M, Tyo J S, Skipper M C, et al. Interaction between geometric parameters and output waveforms in high-power quarter-wave oscillators[J]. IEEE Trans Plasma Science, 2010, 38(5): 1124-1131.
[10] Tyo J S, Skipper M C, Abdalla M D, et al. Development of a high-voltage tunable source for wideband and mesoband effects testing[J]. IEEE Trans Plasma Science, 2010, 38(6): 1450-1461.
[11] Xu G, Liao Y, Xie P, et al. Frequency-tunable high-power mesoband microwave radiator[J]. IEEE Trans Plasma Science, 2011, 39(2): 652-658.
[12] Wang Yuwei, Chen Dongqun, Zhang Jiande, et al. Investigation of a compact coaxially fed switched oscillator[J]. Review of Scientific Instruments, 2013, 84: 094705.
[13] Vega F, Rachidi F. A switched oscillator geometry inspired by a curvilinear space—Part I: DC considerations[J]. IEEE Trans Plasma Science, 2016, 44(10): 2240-2248.
[14] Vega F, Rachidi F. A switched oscillator geometry inspired by a curvilinear space—Part II: Electrodynamic considerations[J]. IEEE Trans Plasma Science, 2016, 44(10): 2249-2257.
[15] Wang Yuwei, Chen Dongqun, Zhang Jiande, et al. Investigation of a switched oscillator filled with oil[J]. High Power Laser and Particle Beams, 2016, 28: 053006.
[16] Song Heng, Chen Dongqun, Wang Yuwei, et al. Simulation and design of electric-magnetic vibrator combined antenna for radiation of wideband high power microwave[J]. High Power Laser and Particle Beams, 2016, 28: 033027.
[17] Wang Yuwei, Chen Dongqun, Zhang Jiande, et al. A compact pulsed power driving source for wideband high power microwave radiation[J]. Journal of THz Science and Electronic Information Technology, 2016, 14(2): 224-228.
王俞卫, 陈冬群, 张自成, 曹胜光, 李达. 一种基于油介质开关振荡器的紧凑宽带高功率微波源[J]. 强激光与粒子束, 2019, 31(1): 013002. Wang Yuwei, Chen Dongqun, Zhang Zicheng, Cao Shengguang, Li Da. A compact wideband high power microwave source based on oil-filled switched oscillator[J]. High Power Laser and Particle Beams, 2019, 31(1): 013002.
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