References
- Gilmour AS. Klystrons, traveling wave tubes, magnetrons, crossed-field amplifiers, and gyrotrons. Boston, London: Artech House; 2011.
- Kartikeyan MV, Boris E, Thumm MKA. Gyrotrons: high power microwave and millimeter wave technology. Berlin, Heidelberg: Springer-Verlag; 2004.
- Thumm MKA. State-of-the-art of high power gyro- devices and free electron masers, Update 2016. Karlsruhe: KIT; 2017.
- Nusinovich GS. Introduction to the physics of gyrotron. Maryland: JHU; 2004.
- Edgecombe CJ. Gyrotron oscillators: their principles and practice. London: Taylor & Francis Ltd; 1993.
- McAulay AD. Military laser technology for defense. Hoboken (NJ): John Wiley & Sons; 2011.
- Kumar N, et al. A review on the applications of high power, high frequency microwave source: gyrotron”. J Fusion Energy. 2011;30(4):257–276.
- Anderson JP. Experimental study of a 110-GHz gyrotron oscillator. Cambridge (MA): Massachusetts Institute of Technology; 2005, p. 171.
- Spraggle P, Derobot AT. The linear and self-consistent nonlinear theory of the electron cyclotron maser instability. IEEE Trans Microwave Theory Tech. June 1977;25:136–137.
- Fliflet AW, Read ME, Chu KR, et al. A self consistent field theory for gyrotron oscillator. Int J Electron. 1982;53:505–521.
- Ganguly AK, Ahn S. Self consistent large signal theory of the gyrotron traveling wave amplifier. Int J Electron. 1982;53:641–658.
- Fliflet AW, Read ME. Use of weakly irregular waveguide theory to calculate eigen-frequencies, Q values, and RF field function for gyrotron oscillators. Int J Electron. 1981;51:475–484.
- Dumbrajs O, Shenggang L. Kinetic theory of electron-cyclotron resonance masers with asymmetry of the electron beam in a cavity. IEEE Trans Plasma Sci. 1992;20(3):126–132.
- Botton M, Antonsen Jr TM. MAGY: a time-dependent code for simulation of slow and fast wave microwave sources. IEEE Trans Plasma Sci. 1998;26(3):882–892.
- Karmakar S, Jain PK, Kumar L, et al. A simple algorithm for large Signal analysis of a gyro-TWT). IEEE international vacuum electronics conference (IVEC); 2007.
- Kolosov SV, Kuraev AA. Nonlinear radiation and converting the longitudinal energy of a relativistic electron beam in a strong rotating electromagnetic fields. Radiotech Electron. 1973;18(12):2558–2566.
- Kolosov SV, Kurayev AA. Nonlinear theory of gyroresonance devices with the irregular electrodynamic system. Electromagn Waves Electron Syst Moscow. 1998;3(1):35–44.
- Kurayev AA, Kolosov SV, Stekolnikov AF, et al. TWT-gyrotrons: non-linear theory, optimization and analysis. Int J Electron. 1988;65(3):437–462.
- Kurayev AA, Kolosov SV, Slepyan AY, et al. Gyrotrons: relativistic case, E and H modes, output converter desiqn. Int J Electron. 1992;72(5):5–6.
- Batura MP, Kuraev AA, Sinitsyn AK. Modeling and optimization of high-power microwave electronic devices. Internal Rep BSUIR. 2006;1:10–55.
- Karmakar S, Sudhakar R, Mudiganti J, et al. Electrical and thermal design of a W-band gyrotron interaction cavity. IEEE Trans Plasma Sci. 2019;47(7):3155–3159.
- Bhanu Naidu V, Kesari V, Karmakar S, et al. Particle in cell simulation of a tapered cavity for a millimeter wave gyrotron. IEEE Trans Plasma Sci. 2018;46(7):2460–2464.
- Shahana K, Kesari V, Karmakar S, et al. Simulation of TE6,2 to Gaussian mode converter for a 95 GHz gyrotron. IEEE Trans Plasma Sci. 2018;46(1):84–89.
- User Manual of Gyro-K.