Book contents
- Microwave and RF Vacuum Electronic Power Sources
- Reviews
- The Cambridge RF and Microwave Engineering Series
- Microwave and RF Vacuum Electronic Power Sources
- Copyright page
- Dedication
- Contents
- Preface
- Principal Roman Symbols
- Principal Greek Symbols
- Abbreviations
- 1 Overview
- 2 Waveguides
- 3 Resonators
- 4 Slow-Wave Structures
- 5 Thermionic Diodes
- 6 Triodes and Tetrodes
- 7 Linear Electron Beams
- 8 Electron Flow in Crossed Fields
- 9 Electron Guns
- 10 Electron Collectors and Cooling
- 11 Beam-Wave Interaction
- 12 Gridded Tubes
- 13 Klystrons
- 14 Travelling-Wave Tubes
- 15 Magnetrons
- 16 Crossed-Field Amplifiers
- 17 Fast-Wave Devices
- 18 Emission and Breakdown Phenomena
- 19 Magnets
- 20 System Integration
- Appendix: Mathcad Worksheets
- Index
- References
16 - Crossed-Field Amplifiers
Published online by Cambridge University Press: 27 April 2018
Book contents
- Microwave and RF Vacuum Electronic Power Sources
- Reviews
- The Cambridge RF and Microwave Engineering Series
- Microwave and RF Vacuum Electronic Power Sources
- Copyright page
- Dedication
- Contents
- Preface
- Principal Roman Symbols
- Principal Greek Symbols
- Abbreviations
- 1 Overview
- 2 Waveguides
- 3 Resonators
- 4 Slow-Wave Structures
- 5 Thermionic Diodes
- 6 Triodes and Tetrodes
- 7 Linear Electron Beams
- 8 Electron Flow in Crossed Fields
- 9 Electron Guns
- 10 Electron Collectors and Cooling
- 11 Beam-Wave Interaction
- 12 Gridded Tubes
- 13 Klystrons
- 14 Travelling-Wave Tubes
- 15 Magnetrons
- 16 Crossed-Field Amplifiers
- 17 Fast-Wave Devices
- 18 Emission and Breakdown Phenomena
- 19 Magnets
- 20 System Integration
- Appendix: Mathcad Worksheets
- Index
- References
Summary
In a magnetron oscillator electrons emitted from a cylindrical cathode interact with the π-mode resonance of a cylindrical, re-entrant, slow-wave structure on the anode. The electrons move under the influence of a radial static electric field and an axial magnetic field. Rotating spokes of charge synchronous with the wave on the anode are formed on the surface of a space-charge hub. As the electrons drift outwards along the spokes the change in potential energy is converted to r.f. energy with high efficiency. Because a magnetron is an oscillator its steady-state operation is always non-linear. Care must be taken in the design of the anode and in the operation of the tube to avoid excitation of modes other than the π-mode. The design of the anode is considered in detail. The performance of magnetrons is reviewed including the effects of the external match on frequency, power output and efficiency. Useful understanding of the properties of a magnetron can be gained from a model which assumes a fixed hub, determined by the theory of the cut-off magnetron diode, and rigid spokes. This model reproduces all the main features of the performance of a magnetron.
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- Information
- Microwave and RF Vacuum Electronic Power Sources , pp. 629 - 658Publisher: Cambridge University PressPrint publication year: 2018
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