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Table of Contents
Intro
Preface
Contents
About the Author
Acronyms
List of Figures
List of Tables
Part I Basics Principles of the Radiolocation
1 Radiolocation and Its Basic Principles
1.1 Standard Radar Systems
1.2 Physical Phenomena Used in Modern Radiolocation
1.3 Distance Measurement Method Using a Pulse Radar
1.4 Short Range Altimeter as an Example of Radars Using Frequency Modulation Signals
1.5 Standard Methods for Determining the Angular Coordinates of Objects
References
2 Determining the Object's Position by Radiolocation Methods
2.1 The Direction of Arrival (DOA) Method
2.2 The Time Difference of Arrival (TDOA) Method
References
3 Reflective Surface of the Detected Objects with Monostatic and Bistatic Radar Systems
3.1 The Reflective Surface Determined for a Monostatic Primary Radar System
3.2 The Reflection Surface of a Group Object
3.3 Monostatic and Bistatic Reflective Surfaces of the Conductive Sphere
3.4 Radar Cross Section of an Object Determined FSR
References
4 Range Equations of Primary and Secondary Radar Systems
4.1 Range Equation of the Primary Radar System
4.2 The Range Equation of the Secondary Radar System
References
5 Bistatic Radar Systems
5.1 Main Advantages and Disadvantages of the Bistatic System
5.2 Methods of Determining Object's Position Using Bistatic Radar System
5.3 Range Equation of the Bistatic Radar System
5.4 Searching Space Using the Probe Signal Chasing Method
References
6 Multistatic Radar Systems
6.1 The Method of Determining the object's Position Using a Multistatic System with One Transmitter and Four Receivers
6.2 The Method of Determining the Velocity Vector of an Object in 3D Space
6.3 The Simulation Tests Results
References
7 Standard Methods for Extending the Range of Radar Station
7.1 Elements of the Radar Signals Theory
7.2 The Additive Reception
7.3 The Correlation Reception
References
8 Theoretical Basis of Matched Signal Filtration
8.1 Convolution
8.2 The Transmittance of a Matched Filter to a Given Signal
8.3 Examples of Standard Signals Matched Filters
References
9 Filters Matched to the Typical Radar Signals
9.1 Filter Matched to a LFM Signal
9.2 Filters Matched to High Frequency Pulses with Bistate Phase Modulation
9.3 Introduction to a Digital Matched Filtration of Radar Signals
9.4 Matched Filtration in Time Domain
9.5 A Matched Filtration in the Frequency Domain
References
10 Basic Methods for Eliminating Spurious Signals
10.1 Basic Methods of Eliminating Signals Reflected from Terrain Obstacles
10.2 Moving Objects' Reflections Elimination Methods
References
11 Searching the Three-Dimensional Space with Radar Devices
11.1 The Three-Dimensional Space Observation Methods
11.2 Observation of the Land and Sea Areas with Radar Devices Installed on Board of Aircrafts
Preface
Contents
About the Author
Acronyms
List of Figures
List of Tables
Part I Basics Principles of the Radiolocation
1 Radiolocation and Its Basic Principles
1.1 Standard Radar Systems
1.2 Physical Phenomena Used in Modern Radiolocation
1.3 Distance Measurement Method Using a Pulse Radar
1.4 Short Range Altimeter as an Example of Radars Using Frequency Modulation Signals
1.5 Standard Methods for Determining the Angular Coordinates of Objects
References
2 Determining the Object's Position by Radiolocation Methods
2.1 The Direction of Arrival (DOA) Method
2.2 The Time Difference of Arrival (TDOA) Method
References
3 Reflective Surface of the Detected Objects with Monostatic and Bistatic Radar Systems
3.1 The Reflective Surface Determined for a Monostatic Primary Radar System
3.2 The Reflection Surface of a Group Object
3.3 Monostatic and Bistatic Reflective Surfaces of the Conductive Sphere
3.4 Radar Cross Section of an Object Determined FSR
References
4 Range Equations of Primary and Secondary Radar Systems
4.1 Range Equation of the Primary Radar System
4.2 The Range Equation of the Secondary Radar System
References
5 Bistatic Radar Systems
5.1 Main Advantages and Disadvantages of the Bistatic System
5.2 Methods of Determining Object's Position Using Bistatic Radar System
5.3 Range Equation of the Bistatic Radar System
5.4 Searching Space Using the Probe Signal Chasing Method
References
6 Multistatic Radar Systems
6.1 The Method of Determining the object's Position Using a Multistatic System with One Transmitter and Four Receivers
6.2 The Method of Determining the Velocity Vector of an Object in 3D Space
6.3 The Simulation Tests Results
References
7 Standard Methods for Extending the Range of Radar Station
7.1 Elements of the Radar Signals Theory
7.2 The Additive Reception
7.3 The Correlation Reception
References
8 Theoretical Basis of Matched Signal Filtration
8.1 Convolution
8.2 The Transmittance of a Matched Filter to a Given Signal
8.3 Examples of Standard Signals Matched Filters
References
9 Filters Matched to the Typical Radar Signals
9.1 Filter Matched to a LFM Signal
9.2 Filters Matched to High Frequency Pulses with Bistate Phase Modulation
9.3 Introduction to a Digital Matched Filtration of Radar Signals
9.4 Matched Filtration in Time Domain
9.5 A Matched Filtration in the Frequency Domain
References
10 Basic Methods for Eliminating Spurious Signals
10.1 Basic Methods of Eliminating Signals Reflected from Terrain Obstacles
10.2 Moving Objects' Reflections Elimination Methods
References
11 Searching the Three-Dimensional Space with Radar Devices
11.1 The Three-Dimensional Space Observation Methods
11.2 Observation of the Land and Sea Areas with Radar Devices Installed on Board of Aircrafts