Nonlinear time-domain analysis of coupled-cavity traveling-wave tubes

A time-dependent nonlinear analysis of a coupled-cavity traveling-wave tube (CCTWT) is presented. The coupled-cavity structure is modeled by a set of equivalent circuit equations where the equations for currents and voltages are coupled to the nearest neighbor cavities. Input and output coupler models as well as sever cavities are included in the formulation. The electron dynamics are treated using the three-dimensional Lorentz force equations although the RF field representation is an analytic model based on cylindrically symmetric geometry. The magnetic focusing fields are also cylindrically symmetric and can be either a solenoid or a periodic permanent magnet stack. The space-charge fields are found by mapping charge to a two-dimensional grid (r, z) and solving Poisson's equation by a finite difference grid formulation. The circuit and Lorentz force equations are integrated in time in a self-consistent manner. The formulation is capable of treating multiple drive frequencies and the associated intermodulation products as well as oscillations and backward wave instabilities. Hence, the model can be used to perform stability analyses. Furthermore, the cavity parameters can be varied to model dynamic velocity tapering for efficiency enhancement. The simulation is applied to the analysis of a sample C-Band CCTWT, and comparisons with measured performance of a Ka-Band CCTWT at Communications and Power Industries, Palo Alto, CA, are made.

[1]  Charles K. Birdsall,et al.  A time-domain circuit simulator for coupled-cavity traveling-wave tubes , 2001 .

[2]  J.R.M. Vaughan,et al.  Calculation of coupled-cavity TWT performance , 1975, IEEE Transactions on Electron Devices.

[3]  J. A. Ruetz,et al.  High-power linear-beam tubes , 1973 .

[4]  Richard G. Carter,et al.  Representation of coupled-cavity slow-wave structures by equivalent circuits , 1983 .

[5]  Baruch Levush,et al.  Advances in modeling and simulation of vacuum electronic devices , 1999, Proc. IEEE.

[6]  Victor L. Granatstein,et al.  Vacuum electronics at the dawn of the twenty-first century , 1999, Proc. IEEE.

[7]  A. S. Gilmour Principles of Traveling Wave Tubes , 1994 .

[8]  V. Srivastava,et al.  A fast large-signal model for coupled-cavity TWTs , 1988 .

[9]  J. D. Wilson,et al.  Simulation of cold-test parameters and RF output power for a coupled-cavity traveling-wave tube , 1995 .

[10]  Richard G. Carter,et al.  Determination of sever positions in coupled-cavity TWTs , 1991 .

[11]  D. R. Whaley,et al.  CTLSS-an advanced electromagnetic simulation tool for designing high-power microwave sources , 2000 .

[12]  J. D. Wilson Design of high-efficiency wide-bandwidth coupled-cavity traveling-wave tube phase velocity tapers with simulated annealing algorithms , 2001 .

[13]  C. Birdsall,et al.  Plasma Physics via Computer Simulation , 2018 .

[14]  H. G. Kosmahl,et al.  Generalized representation of electric fields in interaction gaps of klystrons and traveling-wave tubes , 1972 .

[15]  William H. Press,et al.  Numerical recipes , 1990 .

[16]  J. D. Wilson,et al.  A high-efficiency ferruleless coupled-cavity traveling-wave tube with phase-adjusted taper , 1990 .

[17]  Carol L. Kory,et al.  Simulation of TunneLadder traveling-wave tube cold-test characteristics: Implementation of the three-dimensional, electromagnetic circuit analysis code micro-SOS , 1993 .

[18]  Richard G. Carter,et al.  Design of phase velocity tapers in coupled-cavity TWTs , 1991 .

[19]  H. Curnow,et al.  A General Equivalent Circuit for Coupled-Cavity Slow-Wave Structures , 1965 .

[20]  J. D. Wilson Computationally generated velocity taper for efficiency enhancement in a coupled-cavity traveling-wave tube , 1989 .

[21]  Time-dependent simulation of helix traveling wave tubes , 2000 .