Absolute instability and transient growth near the band edges of a traveling wave tube

Antoulinakis, Foivos; Wong, Patrick; Jassem, Abhijit; Lau, Y. Y.

doi:10.1063/1.5028385

Cited by 10 publications

(3 citation statements)

References 13 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Noteworthily, the absolute instability near the zero group velocity points, similar to the condition in the present study, has recently been carefully re-examined using the BBC, for the conventional traveling-wave tube cases. 50,51 On the other hand, it is important to clarify similarities and differences between the findings presented in this paper and the predictions of classical theories linked to the backward-wave oscillator (BWO) and the traveling-wave tube (TWT). During the linear and start-oscillation stages, as illustrated in Figs.…”

Section: Dominated Instability and Comparison With Theoretical Predic...mentioning

confidence: 86%

Intrinsic resonance in gyrotron using non-resonant RF structure

Yang,

Yao,

Chen

et al. 2024

Physics of Plasmas

View full text Add to dashboard Cite

Gyromonotrons are typically believed to rely on the convective interaction between the co-propagating beam and wave, with the extended energy-exchanging process stemming from the external feedback. However, numerous studies focusing on both transverse electric (TE) mode and transverse magnetic (TM) mode gyrotrons have consistently shown that beam–wave interactions in weak-feedback systems or even in uniform tubes without any structural feedback can yield a theoretical beam efficiency of more than 30% with major forward-wave output during near-cutoff operation, which is the typical operating condition for gyromonotrons. These intriguing findings raise questions about the actual feedback mechanism of gyromonotrons. In this article, comparative studies on the linear and nonlinear behaviors of uniform-tube gyrotron are investigated. The forward and backward waves are observed to co-generate and exhibit similar characteristics of ultra-slow group velocity under near-cutoff operation. This situation allows the as-generated forward wave to modulate the fresh beam, establishing a new backward-wave-like internal feedback loop. Additionally, the quasi-degenerate nature of the bi-directional propagating waves ensures their intrinsic in-phase relationship. The consequent constructive interference enables the uniform tube to function as a high-Q resonator. These findings are found to be independent of the choices of TE or TM modes, providing valuable insights into the underlying interaction mechanism of gyrotron devices.

show abstract

Section: Dominated Instability and Comparison With Theoretical Predic...mentioning

confidence: 86%

Intrinsic resonance in gyrotron using non-resonant RF structure

Yang,

Yao,

Chen

et al. 2024

Physics of Plasmas

View full text Add to dashboard Cite

show abstract

“…pulse propagation 44 ) and include harmonics in nonlinear regimes. This advantage was used [45][46][47] to investigate instabilities [48][49][50] at cutoff (near the edge of the transmission band) of TWTs where frequency models have difficulties to describe the situation. Originally, the discrete model was developed to investigate those regimes, especially for coupled cavity TWTs.…”

Section: Wave Propagation With the Discrete Modelmentioning

confidence: 99%

Time simulation of the nonlinear wave–particle interaction in meters-long traveling-wave tubes

et al. 2021

View full text Add to dashboard Cite

We propose a multi-particle self-consistent Hamiltonian (derived from an N -body description) that is applicable for periodic structures such as traveling-wave tubes (TWTs), gyrotrons, free-electron lasers, or particle accelerators. We build a 1D symplectic multi-particle algorithm to simulate the nonlinear wave-particle interaction in the time domain occurring in an experimental 3-meters long helix TWT. Our algorithm is efficient thanks to a drastic reduction model. A 3D helix version of our reduction model is provided. Finally, we establish an explicit expression of the electromagnetic power in the time domain and in non-monochromatic (non "continuous waveform") regime.

show abstract

“…Nevertheless, it still fails to describe the situation at the cutoff (near the edge of the transmission band) where Pierce's coupling impedance tends to infinity. This situation, widely studied [14][15][16][17][18], is critical since it generates unwanted oscillations for TWTs. We suggested elsewhere [19] that frequency domain envelope models (not only Pierce's), having the same issue, slightly violate Maxwell equations when coupling is strong.…”

Section: Introduction and Motivationsmentioning

confidence: 99%

Recent discrete model for small-signal analysis of traveling-wave tubes

et al. 2019

View full text Add to dashboard Cite

equipe turbulence plasma, case 322 campus Saint Jérôme, av. esc. Normandie-Niemen, To perform accurate numerical simulations of the wave-particle interaction as it occurs in particular in traveling wave tubes, a new approach using field decomposition with large reduction of degrees of freedom has been proposed : the discrete model. To assess its validity, we compare it with the well-established Pierce equivalent circuit model in small signal regime.Before the comparison, the beam-wave interaction in both models is reformulated using a new pedagogical approach, dealing with associated beam, circuit-beam, and circuit impedances.We show analytically and with a numerical example that the newly developed reduced model is very close to the Pierce model. Interestingly, small deviations do exist at the edges of the amplification band, for which the reduced model offers a physical interpretation. PACS numbers: 84.40.Fe (Microwave tubes), 52.40.Mj (Particle beam interaction in plasmas)

show abstract

Absolute instability and transient growth near the band edges of a traveling wave tube

Cited by 10 publications

References 13 publications

Intrinsic resonance in gyrotron using non-resonant RF structure

Intrinsic resonance in gyrotron using non-resonant RF structure

Time simulation of the nonlinear wave–particle interaction in meters-long traveling-wave tubes

Recent discrete model for small-signal analysis of traveling-wave tubes

Contact Info

Product

Resources

About