Investigation of low-voltage broadband overmoded folded rectangular coaxial waveguide TWT at W-band

Duo XU; Shao-Meng WANG; Wei SHAO; Teng-Long HE; He-Xin WANG; Tao TANG; Hua-Rong GONG; Zhi-Gang LU; Zhan-Liang WANG; Zhao-Yun DUAN; Yan-Yu WEI; Jin-Jun FENG; Yu-Bin GONG

doi:10.11972/j.issn.1001-9014.2020.04.005

[1] R K Sharma, A Grede, S Chaudhary. Design of folded waveguide slow-wave structure for W-Band TWT. IEEE Transactions on Plasma Science, 42, 3430-3436(2014).

[2] J J Feng, J Cai, Y F Hu. Development of W-band folded waveguide pulse TWTs. IEEE Transactions on Electron Devices, 60, 1721-1725(2014).

[3] Y Y Wei, G Guo, Y B Gong. Novel W-band ridge-loaded folded waveguide traveling wave tube. IEEE Electron Device Letters, 35, 1058-1060(2014).

[4] J Cai, J J Feng, Y F Hu. 10 GHz Bandwidth 100 Watt W-band folded waveguide pulsed TWTs. IEEE Microwave and Wireless Components Letters, 24, 620-621(2014).

[5] L W Liu, Y Y Wei, F Shen. A Novel Winding Microstrip meander-line slow wave structure for V-band TWT. IEEE Electron Device Letters, 34, 1325-1327(2013).

[6] C Chua, S Aditya. A 3-D U-shaped meander-line slow-wave structure for traveling-wave-tube applications. IEEE Transactions on Electron Devices, 60, 1251-1256(2013).

[7] C Chua, S Aditya, Z X Shen. Design of a planar helix with straight-edge connections for traveling-wave tube applications. India, 207-208(2011).

[8] N F Bai, L L Gu, C S Shen. S-shaped microstrip meander-line slow-wave structure for W-band traveling-wave tube. France, 1-2(2013).

[9] G Ulisse, V Krozer. Investigation of a planar metamaterial slow wave structure for traveling wave tube applications. UK, 1-2(2017).

[10] A I Benedik, N M Ryskin. Planar V-Band Slow-Wave Structures for Low-Voltage Tubes with Sheet Electron Beam. UK, 1-2(2017).

[11] S M Wang, Y B Gong, Y Hou. Study of a log-periodic slow wave structure for Ka-band radial sheet beam traveling wave tube. IEEE Transactions on Plasma Science, 41, 2277-2282(2013).

[12] H X Wang, Z L Wang, X Y Li. Study of a miniaturized dual-beam TWT with planar dielectric-rods-support uniform metallic meander line. physics of plasmas, 25(2018).

[13] Y H Cho, H J Eom. Fourier transform analysis of a ridge-waveguide and a rectangular coaxial line. Radio Science, 36, 533-538(2001).

[14] J H Booske, M C Converse, C L Kory. Accurate parametric modeling of folded waveguide circuits for millimeter-wave traveling wave tubes. IEEE Transactions on Electron Devices, 52, 685-694(2005).

[15] M Sumathy, K J Vinoy, S K Datta. Analysis of ridge-loaded folded-waveguide slow-wave structures for broadband traveling-wave tubes. IEEE Transactions on Electron Devices, 57, 1440-1446(2010).

[16] Y Hou, Y B Gong, J Xu. A novel ridge-vane-loaded folded-waveguide slow-wave structure for 0.22 THz traveling-wave tube. IEEE Transactions on Electron Devices, 60, 1228-1235(2013).

[17] J R Pyle. The cutoff wavelength of the TE₁₀ mode in ridged rectangular waveguide of any aspect ratio. IEEE Transactions on Microwave Theory and Techniques, 14, 175-183(1966).

[18] D M Pozar. Microwave engineering. NY(2004).

[20] A G Williamson. Analysis and modeling of a coaxial-line/rectangular-waveguide junction. Optics and Antennas, 129, 271-277(1982).

[21] S M Saad. A more accurate analysis and design of coaxial-to-rectangular waveguide and launcher. IEEE Transactions on Microwave Theory and Techniques, 38, 129-134(1990).

[22] R B Keam. Broadband design of coaxial line/rectangular waveguide probe transition. Antennas and Propagation, 141, 53-58(1994).

[23] V A Rudakov, V A Sledkov, A P Mayorov. Compact wide-band coaxial-to waveguide microwave transactions for X and Ku bands. Ukraine, 522-523(2013).