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Radar Equations for Modern Radar.
Based on the classic Radar Range-Performance Analysis from 1980, this practical volume extends that work to ensure applicability of radar equations to the design and analysis of modern radars. This unique book helps you identify what information on the radar and its environment is needed to predict...
| Clasificación: | Libro Electrónico |
|---|---|
| Autor principal: | |
| Formato: | Electrónico eBook |
| Idioma: | Inglés |
| Publicado: |
Norwood :
Artech House,
2012.
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| Colección: | Artech House radar library.
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| Temas: | |
| Acceso en línea: | Texto completo |
Tabla de Contenidos:
- Radar Equations for Modern Radar; Contents; Preface; Chapter 1 Development of the Radar Equation; 1.1 Radar Equation Fundamentals; 1.1.1 Maximum Available Signal-to-Noise Ratio; 1.1.2 Minimum Required Signal-to-Noise Ratio; 1.1.3 Maximum Detection Range for Pulsed Radar; 1.2 The Original Radar Equation; 1.3 Blake's Radar Equation for Pulsed Radar; 1.3.1 Significance of Terms in Blake's Equation; 1.3.2 Methods of Solving for Range; 1.3.3 Advantages of the Blake Chart; 1.3.4 Blake's Coherent Radar Equation; 1.3.5 Blake's Bistatic Range Equation; 1.4 other forms of the radar equation.
- 1.4.1 Hall's Radar Equations1.4.2 Barton's Radar Equations; 1.5 avoiding Pitfalls in Range Calculation; 1.5.1 System Noise Temperature Ts; 1.5.2 Use of Signal-to-Noise Energy Ratio; 1.5.3 Use of Average Power; 1.5.4 Bandwidth Correction and Matching Factors; 1.5.5 Detectability Factors for Arbitrary Targets; 1.5.6 Pattern-Propagation Factor; 1.5.7 Loss Factors; 1.5.8 Summary of Pitfalls in Range Calculation; 1.6 radar equation for Modern Radar Systems; 1.6.1 Factors Requiring Modifications to the Range Equation; 1.6.1.1 Eclipsing; 1.6.1.2 Sensitivity Time Control (STC).
- 1.6.1.3 Beam Dwell Factor1.6.1.4 Frequency Agility or Diversity; 1.6.1.5 Lens Factor; 1.6.2 Equations Applicable to Modern Radars; 1.6.3 Method of Calculating Detection Range; 1.6.3.1 Example Radar Range Calculation; 1.6.3.2 Example for Solid-State Radar; 1.6.3.3 Example for Radar with STC; 1.6.4 Vertical Coverage Charts; 1.6.5 Required Probability of Detection; 1.7 Summary of radar equation development; References; Chapter 2 The Search Radar Equation; 2.1 Derivation of the Search Radar Equation; 2.2 search sectors for 2-D air surveillance; 2.2.1 Elevation Coverage in 2-D Surveillance.
- 2.2.2 Fan-Beam Pattern for 2-D Surveillance2.2.3 Cosecant-Squared Pattern for 2-D Surveillance; 2.2.4 Coverage to Constant Altitude; 2.2.5 Enhanced Upper Coverage for 2-D Surveillance Radar; 2.2.6 Reflector Antenna Design for 2-D Surveillance Radar; 2.2.7 Array Antennas for 2-D Surveillance Radar; 2.2.8 Example of Required Power-Aperture Product for 2-D Radar; 2.3 Three-Dimensional Air Surveillance; 2.3.1 Stacked-Beam 3-D Surveillance Radars; 2.3.2 Scanning-Beam 3-D Surveillance Radars; 2.3.3 Search Losses in 3-D Surveillance Radar; 2.4 surveillance with multifunction array radar.
- 2.4.1 Example of MFAR Search Sectors2.4.2 Advantages and Disadvantages of MFAR Search; 2.4.3 Example of Search Radar Equation for MFAR; 2.5 the search fence; 2.5.1 Search Sector for the Fence; 2.5.2 Example ICBM Fence; 2.6 Search Losses; 2.6.1 Reduction in Available Energy Ratio; 2.6.2 Increase in Required Energy Ratio; 2.6.3 Summary of Losses; References; References; Chapter 3 Radar Equations for Clutter and Jamming; 3.1 signal-to-interference ratio; 3.2 clutter effect on detection range; 3.2.1 Range-Ambiguous Clutter; 3.2.2 Types of Radar Waveforms; 3.2.3 Clutter Detectability Factor.