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High-Frequency Vacuum Electron Devices

Vacuum electron devices at frequencies of millimeter waves and terahertz play highly important roles in the modern high-data rate and broadband communication systems, high-resolution detection and imaging, medical diagnostics, magnetically confined nuclear fusion, etc. For the fast motion velocity o...

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Bibliographic Details
Main Author: Feng, Jinjun
Other Authors: Gong, Yubin, Du, Chaohai, Cross, Adrian
Format: eBook
Language:English
Published: Basel MDPI - Multidisciplinary Digital Publishing Institute 2022
Subjects:
Surface Roughness
Vacuum Transistors
Energy Industries And Utilities / Bicssc
Beam-wave Interaction
Dnp-nmr
Deep Learning (dl)
Seb
Sheet Beam
Wireless Communication
Carbon Nanotubes
Experimental Test
High Output Power
Pcm Focusing
N/a
Sheet Electron Beam
Phased Array Radar (par)
Phase Congruency
Bragg Reflector
Transmission Line
High Efficiency
History Of Engineering And Technology / Bicssc
D-band
G-band
Slow-wave Structure
Ka-band
Slow-wave Structures
Extended Interaction Klystron (eik)
Meander-line
Fwg
Technology: General Issues / Bicssc
Machine Learning (ml)
Gate Controllability
Transmission Of The Sheet Beam
Cosine-vane
Directional Coupler
Multiple Gap Cavity
Input Coupler
2 × 2 Amplifier Unit
Traveling-wave Tube (twt)
Twt
Focusing System
High-power Microwave
Dual-band
Corrugated Horn
Vacuum Electronics
Traveling Wave Tube
Terahertz Twts
Dyadic Green's Functions
High-order Mode
S-parameters
340 Ghz
Relativistic Klystron Amplifier
Millimeter Wave And Terahertz
Traveling Wave Tube (twt)
Microstrip Line
Miniaturization
Gyro-twt
Microstrip Meander Line Slow Wave Structure (mml-sws)
Slow-wave Structure (sws)
Multi-layered Media
Coaxial Cavity
Field-assisted Thermionic Emission
Phase-velocity Jumping
Multi-beam
Thermal Analysis
Inhomogeneous
Vacuum Electronic Devices
E-band
Electron Optical System
Over-mode
Slow Wave Structure
Online Access:
Collection: Directory of Open Access Books - Collection details see MPG.ReNa
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100 1 |a Feng, Jinjun 
245 0 0 |a High-Frequency Vacuum Electron Devices  |h Elektronische Ressource 
260 |a Basel  |b MDPI - Multidisciplinary Digital Publishing Institute  |c 2022 
300 |a 1 electronic resource (176 p.) 
653 |a surface roughness 
653 |a vacuum transistors 
653 |a Energy industries and utilities / bicssc 
653 |a beam-wave interaction 
653 |a DNP-NMR 
653 |a deep learning (DL) 
653 |a SEB 
653 |a sheet beam 
653 |a wireless communication 
653 |a carbon nanotubes 
653 |a experimental test 
653 |a high output power 
653 |a PCM focusing 
653 |a n/a 
653 |a sheet electron beam 
653 |a phased array radar (PAR) 
653 |a phase congruency 
653 |a Bragg reflector 
653 |a transmission line 
653 |a high efficiency 
653 |a History of engineering and technology / bicssc 
653 |a D-band 
653 |a G-band 
653 |a slow-wave structure 
653 |a Ka-band 
653 |a slow-wave structures 
653 |a extended interaction klystron (EIK) 
653 |a meander-line 
653 |a FWG 
653 |a Technology: general issues / bicssc 
653 |a machine learning (ML) 
653 |a gate controllability 
653 |a transmission of the sheet beam 
653 |a cosine-vane 
653 |a directional coupler 
653 |a multiple gap cavity 
653 |a input coupler 
653 |a 2 × 2 amplifier unit 
653 |a traveling-wave tube (TWT) 
653 |a TWT 
653 |a focusing system 
653 |a high-power microwave 
653 |a dual-band 
653 |a corrugated horn 
653 |a vacuum electronics 
653 |a traveling wave tube 
653 |a Terahertz TWTs 
653 |a dyadic Green's functions 
653 |a high-order mode 
653 |a S-parameters 
653 |a 340 GHz 
653 |a relativistic klystron amplifier 
653 |a millimeter wave and terahertz 
653 |a traveling wave tube (TWT) 
653 |a microstrip line 
653 |a miniaturization 
653 |a Gyro-TWT 
653 |a microstrip meander line slow wave structure (MML-SWS) 
653 |a slow-wave structure (SWS) 
653 |a multi-layered media 
653 |a coaxial cavity 
653 |a Field-Assisted thermionic emission 
653 |a phase-velocity jumping 
653 |a multi-beam 
653 |a thermal analysis 
653 |a inhomogeneous 
653 |a vacuum electronic devices 
653 |a E-band 
653 |a electron optical system 
653 |a over-mode 
653 |a slow wave structure 
700 1 |a Gong, Yubin 
700 1 |a Du, Chaohai 
700 1 |a Cross, Adrian 
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989 |b DOAB  |a Directory of Open Access Books 
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028 5 0 |a 10.3390/books978-3-0365-5447-1 
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082 0 |a 333 
082 0 |a 380 
082 0 |a 600 
082 0 |a 620 
520 |a Vacuum electron devices at frequencies of millimeter waves and terahertz play highly important roles in the modern high-data rate and broadband communication systems, high-resolution detection and imaging, medical diagnostics, magnetically confined nuclear fusion, etc. For the fast motion velocity of electrons in the vacuum medium, they have the advantages of high power and high efficiency, as well as compactness, compared with other present radiation sources, such as solid-state devices.We established the Special Issue of "High-Frequency Vacuum Electron Devices" with the aim of enhancing the exchange of research information on the theory, design, simulation, processes, and development of these devices to promote their applications, and to attract young researchers and engineers starting out in this important field, which is still vital on the basis of modern electronic science and information technology. 

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