Microwave Power Engineering
Generation, Transmission, Rectification
- 1st Edition - January 1, 1968
- Latest edition
- Editor: Ernest C. Okress
- Language: English
- Paperback ISBN:9 7 8 - 1 - 4 8 3 2 - 0 8 9 6 - 1
- Hardback ISBN:9 7 8 - 1 - 4 8 3 1 - 9 7 3 6 - 4
- eBook ISBN:9 7 8 - 1 - 4 8 3 2 - 2 2 3 9 - 4
Microwave Power Engineering, Volume 1: Generation, Transmission, Rectification considers the components, systems, and applications and the prevailing limitations of the microwave… Read more
Microwave Power Engineering, Volume 1: Generation, Transmission, Rectification considers the components, systems, and applications and the prevailing limitations of the microwave power technology. This book contains four chapters and begins with an introduction to the basic concept and developments of microwave power technology. The second chapter deals with the development of the main classes of high-power microwave and optical frequency power generators, such as magnetrons, crossed-field amplifiers, klystrons, beam plasma amplifiers, crossed-field noise sources, triodes, lasers. The third chapter describes the efficient transmission of high microwave power by means of oversize tubular metallic, surface, beam, and free space beam transmission waveguides. The fourth chapter is devoted to the many different approaches to a microwave rectifier. This book will prove useful to microwave power engineers and researcher who are interested in the application areas of the technology.
List of Contributors
Preface
Contents of Volume 2
Chapter 1. Introduction
1.1 General Introduction and Scope of the Book
References
Chapter 2. Generation
2.1 Introduction
I. Introduction
II. Magnetrons as Microwave Power Sources
III. Crossed-Field Amplifiers as Microwave Power Sources
IV. Klystrons as Microwave Power Sources
V. Beam Plasma Amplifiers
VI. Crossed-Field Noise Sources
VII. Triodes as Microwave Power Sources
VIII. Quantum Electronic Power Generators
References
2.2 Magnetrons as Generators of Microwave Power
I. Introduction
II. Summary of Tube Characteristics
III. Magnetron Design for Microwave Heating
IV. Practical Magnetron Design Considerations
V. The Design of Power Supplies for Microwave Heating Systems
VI. The Future of Magnetrons in Microwave Heating Applications
Symbols
References
2.3 Crossed-Field Amplifiers
2.3.1 TheAmplitron
2.3.2 Crossed-Field Amplifiers
2.3.3 Nonreentrant Crossed-Field Amplifiers
2.4 Crossed-Field Noise Generation Devices
I. Introduction
II. The Mechanism of Noise Generation
III. Injected Beam Noise Generators
IV. The Emitting Sole Noise Generator
References
2.5 Power Klystrons and Related Devices
I. Introduction and Historical Outline
II. Design Considerations
III. State-of -the-Art Resonant Klystron
IV. Advancing the State of the Art
V. Conclusions
References
2.6 Power Triodes
I. Introduction
II. Early Forms of Power Triode Electron Tubes
III. Recent High-Performance Titanium-Ceramic Triodes
IV. Summary
References
2.7 Beam-Plasma Amplifiers
I. Introduction
II. Physical Description of Beam-Plasma Interactions
III. Potential Advantages for High-Power Applications
IV. Plasma Production Methods
V. Methods of Coupling to the Amplifier
VI. Present State of Beam-Plasma Amplifiers
VII. Summary
Symbols
References
2.8 Quantum Electronic Devices
I. Introduction
II. Basic Aspects of Quantum Electronic Generators
III. Quantum Electronic Device Considerations
IV. Potential for Quantum Electronic Generators
2.9 Semiconductor Devices
I. Introduction
II. Present Status
III. Comparative Evaluation of Present Semiconductor Microwave Generators
References
2.10 Conclusions
Text
Chapter 3. Transmission
3.1 Introduction
Text
Symbols
References
3.2 Oversize Tubular Metallic Waveguides
I. Introduction
II. Tubular Metallic Waveguides as High-Power Transmission Media
III. Design of Oversize Waveguide Components for High-Power Systems
IV. Conclusions
Symbols
References
3.3 Surface Waveguides
3.3.1 Single-Conductor Surface Waveguides
3.3.2 Screened Surface Waveguides
3.4 Beam Waveguides
I. Basic Types of Beam Waveguides
II. Theory of Beam Waveguides
III. Practical Aspects
Symbols
References
3.5 Free Space Beam Transmission
I. Introduction
II. Range and Theoretical Efficiency
III. Antenna Aspects
IV. Atmospheric Effects
V. Experimental Results
VI. Conclusions
Symbols
References
3.6 Economic Feasibility of Microwave Power Transmission in Circular Waveguide
I. Introduction
II. Power Transmission in a Perfect Right-Circularly Cylindrical Waveguide
III. Power Losses Due to Mode Conversion in an Imperfect Guide
IV. Cost Estimates of an Underground Microwave Power Transmission System Using Foam Wall Guide
V. Cost Estimates of Complete Microwave Power Systems
Symbols
References
3.7 Conclusions
Text
Chapter 4. Rectification
4.1 Introduction
Text
4.2 Solid-State Power Rectifiers
I. Introduction
II. A Full-Wave Bridge Type of Rectifier Mounted in 10.8 x 12.1-cm ID Waveguide
III. Rectification Efficiency Test at 2.44 GHz on Dipole Antenna Arrays with a Full-Wave Bridge Rectifier at the Center of Each Dipole
IV. Arrays of Untuned Bridge Rectifiers, Capacitance Coupled to Free Space
V. Rectification Efficiency Tests on Various Types of Diodes at 2.44, 5.72, and 10.17 GHz
VI. Discussion
VII. Conclusions
References
4.3 Thermionic Diode Rectifier
I. Introduction
II. Design and Performance Characteristics
III. Some Aspects of Thermionic Diode Operation
4.4 Transverse-Wave Rectifier
I. Description of the Device
II. Power Capability
III. Efficiency Capability
IV. Experimental Results
V. Conclusions
Symbols
Reference
4.5 Crossed-Field Rectifier
Text
References
4.6 Klystron Rectifier
I. The Klystron as a Converter
II. RF-to-DC Conversion
III. RF-to-Low-Frequency Conversion
Symbols
References
4.7 RF-to-Dc Energy Conversion in Beam-Type Devices
I. Introduction
II. Interaction Analysis
III. Experimental Results
IV. Collector Segmentation and Depression
V. Conclusions
Symbols
References
4.8 Conclusions
Text
Author Index
Subject Index
- Edition: 1
- Latest edition
- Published: January 1, 1968
- Language: English
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