The most promising in the THz range is traveling-wave tubes (TWTs) and backward-wave tubes (BWTs) on a serpentine-curved (zigzag-rolled) rectangular waveguide. They are implemented in the THz range (220 GHz), although their characteristics are far from satisfactory due to the strict restriction on the tape electron beam width, that does not allow reaching the summarizing beam current optimum level. To replace the zigzag convoluted waveguide with the spiraled for the TWT and BWT on a curved rectangular waveguide is the best way to remove the ribbon beam width restriction. In the early TWT and BWT design a waveguide planar spiral was also flat in the upper and lower parts connected by vertical idle (without beam) transitions. Proposed design can be significantly improved both in relation to the electron interaction process with the waveguide field and in relation to the TWT-BWT manufacturing technology if instead of a planar waveguide spiral, a circular one is used. The article proposes the TWT designing a terahertz rectangular waveguide folded as a circular spiral. The design differs from the previously proposed TWT with a planar-spiral waveguide by the improved interaction conditions between the electron beam and the waveguide field, as well as the manufacturing technology simplification for terahertz range. Based on numerical simulation, it is shown that proposed TWT achieves Gн= 42 ÷ 48dB saturation gain in the 220 GHz range with the waveguide turn number n = 40 ÷ 50. The proposed TWT design on a rectangular waveguide folded in a circular spiral is more technologically advanced than the TWT on a planar-spiral waveguide. In the most necessary 220 GHz range the efficiency is very high and can provide the need for amplifiers and generators in this and other ranges. We also note that the TWT on a spirally folded waveguide can operate in the BWT mode and, moreover, simultaneously in the TWT and BWT modes. The latter is possible in modes close to linear one. The TWT magnetic system of the type described above can be implemented in the form of a permanent magnet with pluses on the TWT end parts. The proposed TWT characteristics can be significantly improved by optimizing the waveguide helical winding pitch. Exactly as it is achieved with using the spiral wire deceleration system. The efficiency of such optimized TWT reaches 70% efficiency.
Published in | World Journal of Applied Physics (Volume 6, Issue 3) |
DOI | 10.11648/j.wjap.20210603.13 |
Page(s) | 52-54 |
Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
Copyright |
Copyright © The Author(s), 2021. Published by Science Publishing Group |
Terahertz TWT, Circular-Spiral Form of Waveguide, Ring-Shaped Electron Beam, 220 GHz, Gain
[1] | Lyon D. B., Theiss A. J. Folded-wave guide high-power millimeter-wave TWTs # IEDM, 1994, p. 918-920. |
[2] | Huarong Gong et. al. High Power K-bang Folded Travelling-Wave Tube-IVEC. 2010; P. 499-500. |
[3] | Han S. T. et al. Synthesis of Folded-Waveguide TWT // IVEC-2002, USA, p. 94-95. |
[4] | Cook A. M. et al. Serpentine waveguide 220 GHz millimeter wave amplifier // IVEC-2012, USA, p. 547-548. |
[5] | Kurayev A. A., Matveyenko V. V., Rak A. O. Travelling Wave Tube: pat. 22050 Resp. Belarus'; data publ. 30.08.2018. |
[6] | Kurayev A. A. Powerful microwave devices. Methods of analysis and optimization// Moscow, Radio and communication. 1986. 208p. |
[7] | Aksenchyk A. V., Kurayev A. A. Powerful microwave devices with discrete interaction (theory and optimization) Minsk Bestprint, 2003. 376p. |
[8] | Kolosov S. V., Kurayev A. A., Sinitsyn A. K., Aksenchyk A. V., Senko A. V. The simulation codes “CEDR”. IVEC-2010. USA. Monterey, pp. 115-116. |
[9] | Shevchik V. N., Kurayev A. A. General dispersion equation of a running wave with a periodic decelerating system // Radio engineering and electronics, 1961, No. 9 1519-1532. |
[10] | Gulgaev Ya. V., Kravchenko V. F., Kurayev A. A., Vavilov-Cherenkov amplifiers with irregular electrodynamic structures // Sov. Phys. Usp. 2004, T. 174, N6, p. 639-655. |
[11] | Kurayev A. A. Theory and optimization of microwave electronic devices, Minsk: Science and technology, 1979. - 334 p. |
[12] | Kurayev A. A, Baiburin V. B., Ilyin E. M. Mathematical models and methods of optimal design of microwave devices / - Minsk: Science and technology, 1989. - 393 p. |
[13] | Batura M. P., Kurayev A. A., Sinitsin A. K. Fundamentals of theory, calculation and optimization of modern electronic microwave devices / - Minsk: Belorus. st. University of Informatics and Radioelectronics, 2007. - 245 p. |
[14] | Navrotskiy A. A., Kurayev A. A., Sinitsin A. K. TWT-O with irregular deceleration systems. Theory and optimization. LAP LAMBERT Academic Publishing, 2011, 123 p. |
[15] | Kurayev A. A., Rak A. O., Gurinovich A. B. Cherenkov amplifiers and generators on irregular waveguides, LAP LAMBERT Academic Publishing, 2017, 118 p. |
APA Style
Alexander Kurayev, Vladimir Matveyenka. (2021). Terahertz TWT on a Rectangular Waveguide Folded in a Circular Spiral. World Journal of Applied Physics, 6(3), 52-54. https://doi.org/10.11648/j.wjap.20210603.13
ACS Style
Alexander Kurayev; Vladimir Matveyenka. Terahertz TWT on a Rectangular Waveguide Folded in a Circular Spiral. World J. Appl. Phys. 2021, 6(3), 52-54. doi: 10.11648/j.wjap.20210603.13
AMA Style
Alexander Kurayev, Vladimir Matveyenka. Terahertz TWT on a Rectangular Waveguide Folded in a Circular Spiral. World J Appl Phys. 2021;6(3):52-54. doi: 10.11648/j.wjap.20210603.13
@article{10.11648/j.wjap.20210603.13, author = {Alexander Kurayev and Vladimir Matveyenka}, title = {Terahertz TWT on a Rectangular Waveguide Folded in a Circular Spiral}, journal = {World Journal of Applied Physics}, volume = {6}, number = {3}, pages = {52-54}, doi = {10.11648/j.wjap.20210603.13}, url = {https://doi.org/10.11648/j.wjap.20210603.13}, eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.wjap.20210603.13}, abstract = {The most promising in the THz range is traveling-wave tubes (TWTs) and backward-wave tubes (BWTs) on a serpentine-curved (zigzag-rolled) rectangular waveguide. They are implemented in the THz range (220 GHz), although their characteristics are far from satisfactory due to the strict restriction on the tape electron beam width, that does not allow reaching the summarizing beam current optimum level. To replace the zigzag convoluted waveguide with the spiraled for the TWT and BWT on a curved rectangular waveguide is the best way to remove the ribbon beam width restriction. In the early TWT and BWT design a waveguide planar spiral was also flat in the upper and lower parts connected by vertical idle (without beam) transitions. Proposed design can be significantly improved both in relation to the electron interaction process with the waveguide field and in relation to the TWT-BWT manufacturing technology if instead of a planar waveguide spiral, a circular one is used. The article proposes the TWT designing a terahertz rectangular waveguide folded as a circular spiral. The design differs from the previously proposed TWT with a planar-spiral waveguide by the improved interaction conditions between the electron beam and the waveguide field, as well as the manufacturing technology simplification for terahertz range. Based on numerical simulation, it is shown that proposed TWT achieves Gн= 42 ÷ 48dB saturation gain in the 220 GHz range with the waveguide turn number n = 40 ÷ 50. The proposed TWT design on a rectangular waveguide folded in a circular spiral is more technologically advanced than the TWT on a planar-spiral waveguide. In the most necessary 220 GHz range the efficiency is very high and can provide the need for amplifiers and generators in this and other ranges. We also note that the TWT on a spirally folded waveguide can operate in the BWT mode and, moreover, simultaneously in the TWT and BWT modes. The latter is possible in modes close to linear one. The TWT magnetic system of the type described above can be implemented in the form of a permanent magnet with pluses on the TWT end parts. The proposed TWT characteristics can be significantly improved by optimizing the waveguide helical winding pitch. Exactly as it is achieved with using the spiral wire deceleration system. The efficiency of such optimized TWT reaches 70% efficiency.}, year = {2021} }
TY - JOUR T1 - Terahertz TWT on a Rectangular Waveguide Folded in a Circular Spiral AU - Alexander Kurayev AU - Vladimir Matveyenka Y1 - 2021/09/27 PY - 2021 N1 - https://doi.org/10.11648/j.wjap.20210603.13 DO - 10.11648/j.wjap.20210603.13 T2 - World Journal of Applied Physics JF - World Journal of Applied Physics JO - World Journal of Applied Physics SP - 52 EP - 54 PB - Science Publishing Group SN - 2637-6008 UR - https://doi.org/10.11648/j.wjap.20210603.13 AB - The most promising in the THz range is traveling-wave tubes (TWTs) and backward-wave tubes (BWTs) on a serpentine-curved (zigzag-rolled) rectangular waveguide. They are implemented in the THz range (220 GHz), although their characteristics are far from satisfactory due to the strict restriction on the tape electron beam width, that does not allow reaching the summarizing beam current optimum level. To replace the zigzag convoluted waveguide with the spiraled for the TWT and BWT on a curved rectangular waveguide is the best way to remove the ribbon beam width restriction. In the early TWT and BWT design a waveguide planar spiral was also flat in the upper and lower parts connected by vertical idle (without beam) transitions. Proposed design can be significantly improved both in relation to the electron interaction process with the waveguide field and in relation to the TWT-BWT manufacturing technology if instead of a planar waveguide spiral, a circular one is used. The article proposes the TWT designing a terahertz rectangular waveguide folded as a circular spiral. The design differs from the previously proposed TWT with a planar-spiral waveguide by the improved interaction conditions between the electron beam and the waveguide field, as well as the manufacturing technology simplification for terahertz range. Based on numerical simulation, it is shown that proposed TWT achieves Gн= 42 ÷ 48dB saturation gain in the 220 GHz range with the waveguide turn number n = 40 ÷ 50. The proposed TWT design on a rectangular waveguide folded in a circular spiral is more technologically advanced than the TWT on a planar-spiral waveguide. In the most necessary 220 GHz range the efficiency is very high and can provide the need for amplifiers and generators in this and other ranges. We also note that the TWT on a spirally folded waveguide can operate in the BWT mode and, moreover, simultaneously in the TWT and BWT modes. The latter is possible in modes close to linear one. The TWT magnetic system of the type described above can be implemented in the form of a permanent magnet with pluses on the TWT end parts. The proposed TWT characteristics can be significantly improved by optimizing the waveguide helical winding pitch. Exactly as it is achieved with using the spiral wire deceleration system. The efficiency of such optimized TWT reaches 70% efficiency. VL - 6 IS - 3 ER -