References
- Siegel PH. Terahertz technology. IEEE Trans Microw Theory Techn. 2002 Mar;50(3):910–928.10.1109/22.989974
- Tonouchi M. Cutting-edge terahertz technology. Nature Photon. 2007 Dec;1:97–105.10.1038/nphoton.2007.3
- Gamzina D, Himes LG, Barchfeld R, et al. Nano-CNC machining of sub-THz vacuum electron devices. IEEE Trans Electron Devices. 2016 Oct;63(10):4067–4073.
- Gamzina D, Li H, Himes L, et al. Nanoscale surface roughness effects on THz vacuum electron device performance. IEEE Trans Nanotechnol. 2016;15(1):85–93.
- Ahmed S, Doychinov V, Mathisen S, et al. UV-LIGA microfabrication of 0.3 THz double corrugated waveguide. J Micromech Microeng. 2017;26(9).
- Paoloni C, David J-F, Durand A, et al.Fast design method for THz backward wave amplifiers. Paper presented at 7th European/UK-China Workshop on Millimeter Waves and Terahertz Technologies (UCMMT 2014); 2014 Sep 2–4; Chengdu; 2014.
- Rowe JE. Travelling wave amplifier analysis. In: Non-linear beam wave interaction phenomena. st ed. New York Academic Press; 1965.
- Paoloni Claudio, Mineo Mauro. Double corrugated rectangular waveguide slow-wave structure for terahertz vacuum devices. IEEE Trans Electron Devices. 2010 Nov;57(11):3169–3175.
- Rower JE. N-beam nonlinear traveling-wave tube amplifier analysis. IRE Trans Electron Devices. 1961 Jul;8:279–283.
- CST. [ Online]. Available from: https://www.cst.com/products/csts2
- Datta SK, Kumar L. Plasma frequency reduction factor. Defence Sci J. 2008 Nov;58(6):768–770.
- Branch GM, Mihran TG. Plasma frequency reduction factors in electron beams. IRE Trans- Electron Devices. 1955;2:3–11.
- MATLAB. [ Online]. Available from : https://uk.mathworks.com/products/matlab/
- Paoloni C, Mineo M. Double corrugagted waveguides for G-band travelling wave tubes. IEEE Trans Eectron Devices. 2014;61(12):4259–4263
- Joo YD, Sinhá AK, Park GS. SINCOHET : simple nonlinear analysis code for helix traveling wave tube. Monterey (CA): IEEE; 2008.