Improved Model for Beam-Wave Interaction With Ohmic Losses and Reflections of Sheet Beam Traveling Wave Tubes

Improved Model for Beam-Wave Interaction With Ohmic Losses and Reflections of Sheet Beam Traveling Wave Tubes

In this article, an improved model for the beam-wave interaction of sheet beam in traveling wave tubes (TWTs) considering ohmic losses and reflections is presented. The ohmic losses are obtained by field analysis and equivalent method. The space charge magnetic field is derived from the active Helmh...

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Veröffentlicht in:IEEE transactions on electron devices 2021-06, Vol.68 (6), p.2977-2983
Hauptverfasser: Tian, Hanwen, Shi, Ningjie, Wang, Zhanliang, Wang, Shaomeng, Duan, Zhaoyun, Gong, Huarong, Lu, Zhigang, Paoloni, Claudio, Feng, Jinjun, Gong, Yubin
Format: Artikel
Sprache:eng
Schlagworte:
Algorithms
Beam-wave interaction
Blades
Electromagnetic fields
Equivalent circuits
Harmonic analysis
Integrated circuit modeling
losses
Macroparticles
Magnetic circuits
Metals
Particle in cell technique
reflections
sheet beam traveling wave tube (TWT)
Simulation
Solid modeling
Space charge
Traveling wave tubes
Traveling waves
Wave interaction
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Zusammenfassung:In this article, an improved model for the beam-wave interaction of sheet beam in traveling wave tubes (TWTs) considering ohmic losses and reflections is presented. The ohmic losses are obtained by field analysis and equivalent method. The space charge magnetic field is derived from the active Helmholtz's equation. An algorithm to obtain the S-matrix by the equivalent circuit method is presented. The relativistic Boris method is applied to accelerate macroparticles. The exchanged power is computed by the work the electromagnetic field applied to the macroparticles. The theoretical model is applied for validation to a {G} -band staggered double vane TWT and validated in comparison with CST Particle Studio and simulations without losses and reflections. The convergence of this algorithm is also discussed. The simulation time of the model is substantial faster than 3-D particle-in-cell (PIC) simulations.
ISSN:0018-9383
1557-9646
DOI:10.1109/TED.2021.3071212