Microwave systems and applications
Author(s)
Bibliographic Information
Microwave systems and applications
(Microwave technology series, 3 . The microwave engineering handbook ; v. 3)
Chapman & Hall, c1993
- : USA
Available at 13 libraries
  Aomori
  Iwate
  Miyagi
  Akita
  Yamagata
  Fukushima
  Ibaraki
  Tochigi
  Gunma
  Saitama
  Chiba
  Tokyo
  Kanagawa
  Niigata
  Toyama
  Ishikawa
  Fukui
  Yamanashi
  Nagano
  Gifu
  Shizuoka
  Aichi
  Mie
  Shiga
  Kyoto
  Osaka
  Hyogo
  Nara
  Wakayama
  Tottori
  Shimane
  Okayama
  Hiroshima
  Yamaguchi
  Tokushima
  Kagawa
  Ehime
  Kochi
  Fukuoka
  Saga
  Nagasaki
  Kumamoto
  Oita
  Miyazaki
  Kagoshima
  Okinawa
  Korea
  China
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  United Kingdom
  Germany
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  France
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  United States of America
Note
Includes bibliographical references and index
Description and Table of Contents
Description
The Microwave Engineering Handbook provides the only complete reference available on microwave engineering. The three volumes of the handbook cover the entire field of microwave engineering, from basic components to system design. All entries in the handbook are written by experts in the area, bringing together an unrivalled collection of expertise on microwave technology. Volume 3: Microwave systems and applications provides a thorough introduction to the principal applications of microwave technology. Telecommunication, broadcasting, detection and ranging and scientific and industrial applications are covered with appendices on microwave measurement and frequency allocation. This volume shows the range of current and developing applications for microwave technology and will enable readers to appreciate the variety of applications and the requirements for the various system types.
Table of Contents
- 1 Point-to-point transmission, terrestrial line-of-sight links, terrestrial troposcatter links.- 1.1 General.- 1.2 Principles of radio relays.- 1.2.1 Repeater functions.- 1.2.2 Carrier frequency utilization.- 1.2.3 Different types of repeaters.- 1.2.4 Different types of terminals.- 1.2.5 Special features of antennas for radio relay links.- 1.2.6 Feeders.- 1.3 Analogue microwave links.- 1.3.1 General.- 1.3.2 Characteristics of the signals transmitted.- 1.3.3 Analogue modulation.- 1.3.4 Technological aspects.- 1.3.5 Operating aid facilities.- 1.3.6 Frequency modulation distortions.- 1.3.7 Performances of analogue microwave links.- 1.3.8 Quality improvement.- 1.3.9 Transmission quality.- 1.4 Digital microwave links.- 1.4.1 Characteristics of the signals transmitted.- 1.4.2 Digital modulation.- 1.4.3 Technological aspects.- 1.4.4 Other specific features of digital microwave links.- 1.4.5 Performances of digital microwave links.- 1.4.6 Techniques used for improving quality.- 1.4.7 Predicting outages due to propagation.- 1.5 Specific nature of over-the-horizon microwave links.- 1.5.1 Properties of the propagation medium.- 1.5.2 Equipment characteristics.- 1.5.3 Transmission quality.- References.- 2 Satellite links.- 2.1 General.- 2.1.1 Introduction.- 2.1.2 Communication satellite systems.- 2.1.3 Utilization of the radio frequency spectrum.- 2.1.4 Specific characteristics.- 2.1.5 Main applications and techniques.- 2.1.6 Historical overview.- 2.1.7 Existing satellite systems.- 2.2 Basic principles.- 2.2.1 The basic satellite communication link.- 2.2.2 Definitions and formulae.- 2.2.3 Other topics.- 2.2.4 The link budget.- 2.2.5 Link quality.- 2.3 Communication satellite technology.- 2.3.1 Communication satellite construction.- 2.3.2 Communication satellite payload.- 2.4 Earth stations.- 2.4.1 General.- 2.4.2 The antenna system.- 2.4.3 The low noise amplifier (LNA).- 2.4.4 Measurements of noise temperatures and antenna G/T.- 2.4.5 The high power amplifier (HPA).- 2.4.6 The up-and down-converters (U/C, D/C).- 2.5 Conclusions and prospects.- References.- 3 Low and medium power translators and transmitters.- 3.1 Optimization of the input design of a television translator.- 3.1.1 Brief review: what are the design possibilities?.- 3.1.2 Optimization of antinomic couple noise factor/input stage linearity.- 3.2 Development of television transmitter modulation stages.- 3.2.1 Vision and sound IF modulation.- 3.2.2 IF vision corrector.- 3.2.3 Non-linearity correction of the vision channel.- 3.2.4 Output wideband converter.- 3.3 Optimization of the output design of a television transmitter or translator and enhancing the level of transistorization.- 3.3.1 Analysis of the distortions generated in a power amplifier.- 3.3.2 Non-linearity correctors.- 3.3.3 Amplifier assemblies.- 3.3.4 Improvement of reliability.- 3.3.5 Overall characteristics of transmitters.- 3.4 Conclusion.- Appendix 3.A The frequency spectrum and broadcasting channels.- 4 Radar systems.- 4.1 The history of radar.- 4.1.1 Before 1935.- 4.1.2 Since 1935
- the pulse radar.- 4.1.3 The angular measurement.- 4.1.4 Pulse compression and coded radars.- 4.1.5 Doppler filtering.- 4.1.6 Electronic scanning.- 4.2 General description of radar systems.- 4.2.1 Basic principles derived from the theory of radar systems.- 4.2.2 About the parasitic noise.- 4.2.3 Radar block diagram.- 4.2.4 About antennas.- 4.2.5 About transmitters.- 4.2.6 About receivers.- 4.2.7 Choice of wavelengths - basic examples of radar parameters.- 4.2.8 Radar cross-section-target fluctuation-stealth targets.- 4.2.9 Problems: analysis of a multifunction radar.- 4.2.10 Pulse compression.- 4.2.11 About digital processing.- 4.2.12 Action against clutter.- 4.2.13 Pulse-Doppler radars.- 4.3 Main applications of radar systems.- 4.3.1 Surveillance radars.- 4.3.2 Fire control radar systems.- 4.3.3 Radar systems on board aircraft.- 4.3.4 Instrumentation radars.- 4.3.5 Other applications.- 4.4 Expected evolution of radar systems.- 4.4.1 Multifunction and multimode in radar systems.- 4.4.2 Present and future implementation of ancient ideas-active antennas.- 4.4.3 High resolution in distance.- 4.4.4 New wavelengths.- References.- 5 Electronic confrontation.- 5.1 Introduction.- 5.2 Electronic support measures (ESM).- 5.2.1 General.- 5.2.2 Reception techniques.- 5.2.3 Direction-finding techniques.- 5.2.4 Location measurements.- 5.2.5 Evolution of the systems.- 5.3 Electronic countermeasures (ECM).- 5.3.1 Introduction.- 5.3.2 Main operational uses of jammers.- 5.3.3 Jamming techniques.- 5.3.4 Main effects of jammers.- 5.3.5 Evolution of jamming facilities.- 5.4 ECCM applied to radio frequency links.- 5.4.1 General.- 5.4.2 Jamming protection techniques.- 5.4.3 Signal interception protection techniques.- 5.4.4 Conclusion.- 5.5 ECCM applied to radars.- 5.5.1 General.- 5.5.2 Radar range in the presence of jamming.- 5.5.3 General principles used against jamming.- 5.5.4 Main ECCM techniques.- 5.6 System design methodology.- 5.6.1 New tools to be incorporated into operational systems.- 5.6.2 Strategic intelligence: an in-depth analysis.- 5.6.3 Tactical intelligence: quick analysis of situations and priorities.- 5.6.4 Self-protection of weapon systems: a highly complex function.- 5.6.5 Air strike: active support at several levels.- 5.6.6 Counter-mobility: neutralization by jamming.- 5.6.7 Radioelectric superiority: preventing the use of the spectrum by the enemy.- 5.6.8 Elimination of the enemy anti-aircraft defence: extensive use of ESM and ECM.- 6 Infrared.- 6.1 Introduction.- 6.1.1 General definition.- 6.1.2 Spectral bands.- 6.1.3 Infrared system classification.- 6.2 Short historical background.- 6.3 Theory notes.- 6.3.1 Optical quantities and relationships.- 6.3.2 Photometry and radiometry.- 6.3.3 Atmosphere.- 6.3.4 Sources.- 6.3.5 Optical materials.- 6.3.6 Detectors.- 6.4 Infrared techniques.- 6.4.1 Instrument design considerations for passive IR detection.- 6.4.2 Performances of passive infrared optronic systems.- 6.4.3 Laser detection techniques.- 6.4.4 IR laser system performance.- 6.5 Military applications of infrared.- 6.5.1 Military applications of passive infrared.- 6.5.2 Military applications of active infrared systems.- 6.5.3 Military applications of semi-active infrared.- 6.5.4 Military applications of point-to-point links.- 6.6 Developments and trends in the infrared field.- 6.6.1 Optical windows and IR domes.- 6.6.2 Stabilization and scanning.- 6.6.3 Optical systems.- 6.6.4 Detectors.- 6.6.5 Cooling devices.- 6.6.6 Laser emitters.- 6.6.7 Processing devices.- 6.6.8 Display.- 7 Industrial, scientific and medical (ISM) applications of microwaves present and prospective.- 7.1 Introduction.- 7.2 High power applications.- 7.2.1 Microwave heating.- 7.2.2 High energy scientific applications.- 7.2.3 The problems of leakage: the personnel exposure standards.- 7.2.4 Conclusion.- 7.3 Active sensors and systems.- 7.3.1 Radar type sensors and miscellaneous.- 7.3.2 Non-destructive control.- 7.3.3 Microwave active imaging.- 7.3.4 Conclusion.- 7.4 Passive sensors and systems.- 7.4.1 Principles.- 7.4.2 Radiometric receivers.- 7.4.3 Applications of radiometry.- 7.4.4 Conclusion.- 7.5 Conclusion.- References.- 8 Radioastronomy.- 8.1 Introduction.- 8.2 Radio telescopes.- 8.2.1 Single dish.- 8.2.2 Interferometry and aperture synthesis.- 8.3 Cosmic radio emission.- 8.3.1 Continuum emission.- 8.3.2 Line emission.- 8.4 Continuum radio sources.- 8.4.1 The Galaxy.- 8.4.2 Extragalactic radio sources.- 8.5 The 21 cm hydrogen line.- 8.6 Interstellar molecules.- 8.6.1 The discovery.- 8.6.2 Astrochemistry.- 8.6.3 Cosmic maser amplification.- 8.6.4 The concept of a two-level maser.- 8.7 Conclusion and prospects.- Appendix 8.A Units and constants in astronomy.- References.- Problems.
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