Design Methodology and Experimental Verification of Serpentine/Folded-Waveguide TWTs

The general electromagnetic properties and design methodology for serpentine/folded-waveguide (FW) amplifiers are presented. In addition, hybrid-waveguide circuit topologies, which permit greater design flexibility than the basic serpentine/FW topologies, are also introduced, and their dispersion ch...

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Veröffentlicht in:	IEEE transactions on electron devices 2014-06, Vol.61 (6), p.1679-1686
Hauptverfasser:	Nguyen, Khanh T., Cooke, Simon J., Levush, Baruch, Abe, David K., Chernin, David P., Chernyavskiy, Igor A., Vlasov, Alexander N., Ludeking, Lars, Joye, Colin D., Cook, Alan M., Calame, Jeffrey P., Pasour, John A., Pershing, Dean E., Wright, Edward L.
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Sprache:	eng
Schlagworte:	Amplifier Amplifiers backward-wave oscillation (BWO) Design methodology Dispersion Dispersions Electromagnetic properties Electron beams Fabrication Flexibility folded waveguide (FW) Methodology oscillation Passband Radio frequency Serpentine stopband Topology traveling-wave tube (TWT) vacuum electronics Wideband
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container_title	IEEE transactions on electron devices
container_volume	61
creator	Nguyen, Khanh T. Cooke, Simon J. Levush, Baruch Abe, David K. Chernin, David P. Chernyavskiy, Igor A. Vlasov, Alexander N. Ludeking, Lars Joye, Colin D. Cook, Alan M. Calame, Jeffrey P. Pasour, John A. Pershing, Dean E. Wright, Edward L.
description	The general electromagnetic properties and design methodology for serpentine/folded-waveguide (FW) amplifiers are presented. In addition, hybrid-waveguide circuit topologies, which permit greater design flexibility than the basic serpentine/FW topologies, are also introduced, and their dispersion characteristics are discussed. Experimental validation of design methodology and tools is provided via test results of the recently demonstrated wideband 220-GHz serpentine amplifier, which embodies the design methodology described herein. Particular attention will be paid to the comparison between code prediction and experimental data, which are in excellent agreement.
doi_str_mv	10.1109/TED.2014.2303711
format	Article
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subjects	Amplifier Amplifiers backward-wave oscillation (BWO) Design methodology Dispersion Dispersions Electromagnetic properties Electron beams Fabrication Flexibility folded waveguide (FW) Methodology oscillation Passband Radio frequency Serpentine stopband Topology traveling-wave tube (TWT) vacuum electronics Wideband
title	Design Methodology and Experimental Verification of Serpentine/Folded-Waveguide TWTs
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