Broadband-Printed Traveling-Wave Tube Based on a Staggered Rings Microstrip Line Slow-Wave Structure

Yang, Ruichao; Yue, Lingna; Xu, Jun; Yin, Pengcheng; Luo, Jinjing; Wang, Hexin; Jia, Dongdong; Zhang, Jian; Yin, Hairong; Cai, Jin-Yi; Guo, Guo; Zhao, Guoqing; Wang, Wenxiang; Li, Dazhi; Wei, Yanyu

doi:10.3390/electronics11030384

Cited by 4 publications

(2 citation statements)

References 19 publications

(23 reference statements)

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“…All these characteristics are fundamental for aerospace applications, in which one of the main goals is to minimize both power consumption and weight. In the last years, several configurations of sheet-beam TWTs have been proposed [6]- [13]. Some of them are able to operate with a very low voltage, such as the one proposed by Wen et al [10]: a concentric arc meander line capable of operating with a voltage of 720 V. A similar configuration, able to work with a voltage of 791 V, has been proposed by Wang et al [11].…”

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confidence: 99%

Design of a Low Voltage and High Power Traveling Wave Tube Based on a Sheet-Beam Rectangular Ring-Bar Slow-Wave Structure

Paterna,

Lipari,

Traina

et al. 2024

IEEE Access

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In this article, a sheet-beam type ring bar slow wave structure (RBSWS) capable of working at very low-voltage value is proposed. The structure is designed to work over the frequency range from 14 to 18 GHz with a cathodic voltage of 2.050 kV and a current of 100 mA. Simulation results for two 50-period sections, carried out by CST Studio Suite 2023, show a saturated output power of 30 W, a maximum gain of 0.795 dB/mm, and an electronic efficiency higher than 15 %. The proposed structure is ideal for aerospace applications that usually require compact size, low weight and power consumption, while maintaining very high output power levels. Furthermore, this device is relatively easy to manufacture, making it a more accessible option than other structures that require complex and expensive manufacturing processes. Finally, the mechanical and thermal dissipation problems are kept under control thanks to the large surface contact between the slow wave structure and the dielectric rod realized in Boron Nitride. INDEX TERMSHigh power amplifiers -Traveling Wave Tubes -Sheet-beam -Low operating voltage -Ring Bar

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confidence: 99%

Design of a Low Voltage and High Power Traveling Wave Tube Based on a Sheet-Beam Rectangular Ring-Bar Slow-Wave Structure

Paterna,

Lipari,

Traina

et al. 2024

IEEE Access

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“…One paper [3] is based on the design of multiple Dielectric-Supported Ridge-Loaded Rhombus-Shaped Wideband Meander-Line Slow-Wave Structures for a V-Band TWT; the simulations show that the structure has a larger bandwidth, higher gain, more stable structure, and better heat dissipation ability. For high-power TWTs with meander-line SWSs, a staggered-ring micro-strip line (SRML) structure [4] is proposed and designed in the paper of "Broadband-Printed Traveling-Wave Tube Based on a Staggered Rings Micro-strip Line Slow-Wave Structure", and the input and output structures with micro-strip probes and transition sections are also shown. The particle-in-cell (PIC) simulation results indicate that the SRML TWT has a maximum output of 322 W at 32.5 GHz under a beam voltage of 9.7 kV and a beam current of 380 mA, and the output power is over 100 W in the frequency range of 27 GHz to 38 GHz.…”

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confidence: 99%