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Radar target detection handbook of theory and practice
| Clasificación: | Libro Electrónico |
|---|---|
| Autores principales: | , |
| Formato: | Electrónico eBook |
| Idioma: | Inglés |
| Publicado: |
New York,
Academic Press,
1973.
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| Colección: | Electrical science series.
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| Temas: | |
| Acceso en línea: | Texto completo |
Tabla de Contenidos:
- Front Cover; Radar Target Detection: Handbook of Theory and Practice; Copyright Page; Table of Content; FOREWORD; PREFACE; ACKNOWLEDGMENTS; LIST OF SYMBOLS; CHAPTER 1. REVIEW OF THE RADA RANG E EQUATION; 1-1 Introduction; 1-2 The Basic Radar Range Equation; 1-3 Noise Bandwidth; 1-4 Noise Factor, Noise Figure, and Effective Noise Temperature; 1-5 The Radar Range Equation for I.F Signal-to-Noise Ratio; 1-6 The Matched (or North) Filter Receiver; 1-7 Marcum's Use of the Radar Range Equation; 1-8 Other Useful Forms of the Radar Range Equation; 1-9 The Energy Radar Range Equation
- 1-10 The Radar Range Equation for a Bistatic System1-11 The Radar Range Equation for a Search Radar; 1-12 Summary of Search and Tracking Radar System Losses; 1-13 Illustrative Example Using the Search Radar Equation; References; CHAPTER 2. STATISTICAL SIGNAL DETECTION; 2-1 Detection; 2-2 False Alarm Time, Probability of False Alarm, and False Alarm Number; 2-3 Probability of False Alarm versus Bias Level Setting; 2-4 Determination of Bias Level Setting; 2-5 The Advantages and Disadvantages of Pulse Integration
- 2-6 General Theory of Probability of Detection as a Function of Probability of False Alarm and Number of Pulses Integrated2-7 Illustrative Examples for Determining Probability of Detection Using Meyer Plots; 2-8 Integration Loss; 2-9 Illustrative Examples for Determining Integration Loss and Integration Efficiency Using Meyer Plots; 2-10 Collapsing Loss; 2-11 Illustrative Example for Determining Collapsing Loss Using Meyer Plots; References; CHAPTER 3. TARGET MODELS AN D THE DETERMINATION OF DETECTION PROBABILITY; 3-1 Introduction and Historical Background
- 3-2 Scattering Cross Section and the Target Modeling Problem3-3 Single-Hit Probability of Detection; 3-4 Definition of a Square-Law Detector; 3-5 The Nonfluctuating Target Model for N Pulse Returns; 3-6 Fluctuating Targets : Swerling's Cases 1 and 2-The Rayleigh Distribution; 3-7 Fluctuating Targets: Swerling's Cases 3 and 4-The Chi-Square Distribution with Four Degrees of Freedom; 3-8 The Relationship between the Five Standard Target Models and Modern Target Models; 3-9 The Linear-Type Envelope Detector; 3-10 Best Possible Detector Law; 3-11 Other Approaches to the Detection Criteria
- 3-12 Application of Pulse Radar Results to CW Radar System3-13 Beam-Shape and Scanning Loss; 3-14 A Method of Using Meyer Plots for Optimizing the Number of Pulses Integrated When Accounting for Beam-Shape Loss; 3-15 Some Other Contributing Losses; References; CHAPTER 4. MEYER PLOTS-DESCRIPTION AN D USE; 4-1 Basics of Meyer Plots and Target Models; 4-2 Illustrative Look-Up Problems Using Meyer Plots and Methods of Interpolation; 4-3 Chi-Square Target Models of Arbitrary Degrees of Freedom; 4-4 Approximation for Rice Power (One-Dominant-Plus-Rayleigh) Target Model