Aerospace Sensors

航天传感器(影印版)(英文版)

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Author: Nebylov A.
Language: English
ISBN/ISSN: 9787560350578
2015-06;  Soft Cover

SERIES PREFACE
PREFACE
ACKNOWLEDGMENTS
ABOUT THE SERIES EDITOR
ABOUT THE EDITOR
1 INTRODUCTION
1.1 General Considerations
1.1.1 Types of Aerospace Vehicles and Missions
1.1.2 The Role of Sensors and Control Systems in Aerospace
1.1.3 Specific Design Criteria for Aerospace Vehicles and their Sensors
1.1.4 Physical Principles Influencing Primary Aerospace Sensor Design
1.1.5 Reference Frames Accepted in Aviation and Astronautics
1.2 Characteristics and Challenges of the Atmospheric Environment
1.2.1 Components of the Earth's Atmosphere
1.2.2 Stationary Models of the Atmosphere
1.2.3 Anisotropy and Variability in the Atmosphere
1.2.4 Electrical Charges in the Atmosphere
1.2.5 Electromagnetic Wave Propagation in the Atmosphere
1.2.6 Geomagnetism
1.2.7 The Planetary Atmosphere
1.3 Characteristics and Challenges of the Space Environment
1.3.1 General Considerations
1.3.2 Near—Earth Space
1.3.3 Circumsolar (Near—Sun) Space
1.3.4 Matter in Space
1.3.5 Distances and Time Scales in Deep Space
References
2 AIR PRESSURE—DEPENDENT SENSORS
2.1 Basic Aircraft Instrumentation
2.2 Fundamental Physical Properties of Airflow
2.2.1 Fundamental Airflow Physical Property Definitions
2.2.1.1 Pressure
2.2.1.2 Air Density
2.2.1.3 Temperature
2.2.1.4 Flow Velocity
2.2.2 The Equation of State for a Perfect Gas
2.2.3 Extension o fDefinitions: Total, Dynamic, Static, and Stagnation
2.2.4 The Speed of Sound and Mach Number
2.2.4.1 The Speed of Sound
2.2.4.2 Mach Number and Compressibility
2.2.5 The Source of Aerodynamic Forces
2.3 Altitude Conventions
2.4 Barometric Altimeters
2.4.1 Theoretical Considerations
2.4.1.1 The Troposphere
2.4.1.2 The Stratosphere
2.4.2 Barometric Altimeter Principles and Construction
2.4.3 Barometric Altimeter Errors
2.4.3.1 Methodical Errors
2.4.3.2 Instrumental Errors
2.5 Airspeed Conventions
2.6 The Manometric Airspeedlndicator
2.6.1 Manometric Airspeedlndicator Principles and Construction
2.6.2 Theoretical Considerations
2.6.2.1 Subsonic Incompressible Operation
2.6.2.2 Subsonic Compressible Operation
2.6.2.3 Supersonic Operation
2.6.3 Manometric Airspeed Indicator Errors
2.6.3.1 Methodical Errors
2.6.3.2 Instrumental Errors
2.7 The Vertical Speed Indicator (VSI)
2.7.1 VSI Principles and Construction
2.7.2 Theoretical Considerations
2.7.2.1 Lag Rate (Time Constant)
2.7.2.2 Sensitivity to Mach Number
2.7.2.3 Sensitivity to Altitude
2.7.3 VSI Errors
2.8 Angles of Attack and Slip
2.8.1 The Pivoted Vane
2.8.2 The Differential Pressure Tube
2.8.3 The Null—Seeking Pressure Tube
References
Appendix
3 RADAR ALTIMETERS
3.1 Introduction
3.1.1 Definitions
3.1.2 Altimetry Methods
3.1.3 General Principles of Radar Altimetry
3.1.4 Classification by Different Features
3.1.5 Application and Performance Characteristics
3.1.5.1 Aircraft Applications
3.1.5.2 Spacecraft Applications
3.1.5.3 Military Applications
3.1.5.4 Remote Sensing Applications
3.1.6 Performance Characteristics
3.2 Pulse Radar Altimeters
3.2.1 Principle of Operation
3.2.2 Pulse Duration
3.2.3 Tracking Altimeters
3.2.4 Design Principles
3.2.5 Features of Altimeters with Pulse Compression
3.2.6 Pulse Laser Altimetry
3.2.7 Some Examples
3.2.8 Validation
3.2.9 Future Trends
3.3 Continuous Wave Radar Altimeters
3.3.1 Principles of Continuous Wave Radar
3.3.2 FMCW Radar Waveforms
3.3.3 Design Principles and Structural Features
3.3.3.1 Local Oscillator Automatic Tuning
3.3.3.2 Single—Sideband Receiver Structure
3.3.4 The Doppler Effect
3.3.5 Alternative Measuring Devices for FMCW Altimeters
3.3.6 Accuracy and Unambiguous Altitude
3.3.7 Aviation Applications
3.4 Phase Precise Radar Altimeters
3.4.1 The Phase Method of Range Measurement
3.4.2 The Two—Frequency Phase Method
3.4.3 Ambiguity and Accuracy in the Two—Frequency Method
3.4.4 Phase Ambiguity Resolution
3.4.5 Waveforms
3.4.6 Measuring Devices and Signal Processing
3.4.7 Remarks on the Accuracy of CW and Pulse Radar Altimeters
3.5 Radioactive Altimeters for Space Application
3.5.1 Motivation and History
3.5.2 Physical Bases
3.5.2.1 Features of Radiation
3.5.2.2 Generators of Photon Emission
3.5.2.3 Receivers
3.5.2.4 Propagation Features
3.5.3 Principles of Operation
3.5.4 Radiation Dosage
3,5.5 Examples of Radioisotope Altimeters
References
4 AUTONOMOUS RADIO SENSORS FOR MOTION PARAMETERS
4.1 Introduction
4.2 Doppler Sensors for Ground Speed and Crab Angle
4.2.1 Physical Basis and Functions
4.2.2 Principle of Operation
4.2.3 Classification and Features of Sensors for Ground Speed and Crab Angle
4.2.4 Generalized Structural Diagram for the Ground Speed'and Crab Angle Meter
4.2.5 Design Principles
4.2.6 Sources of Doppler Radar Errors
4.2.7 Examples
4.3 Airborne Weather Sensors
4.3.1 Weather Radar as Mandatory Equipment of Airliners and Transport Aircraft
4.3.2 Multifunctionality of Airborne Weather Radar
4.3.3 Meteorological Functions of AWR
4.3.4 Principles ofDWP Detection with AWR
4.3.4.1 Developing Methods of DWP Detection
4.3.4.2 Cumulonimbus Clouds and Heavy Rain
4.3.4.3 Turbulence Detection
4.3.4.4 Wind Shear Detection
4.3.4.5 Hail Zone Detection
4.3.4.6 Probable Icing—in—flight Zone Detection
4.3.5 Surface Mapping
4.3.5.1 Comparison of Radar and Visual Orientation
4.3.5.2 The Surface—Mapping Principle
4.3.5.3 Reflecting Behavior ofthe Earth's Surface
4.3.5.4 The Radar Equation and Signal Correction
4.3.5.5 Automatic Classification of Navigational Landmarks
4.3.6 AWR Design Principles
4.3.6.1 The Operating Principle and Typical Structure of AWR
4.3.6.2 AWR Structures
4.3.6.3 Performance Characteristics: Basic Requirements
4.3.7 AWR Examples
4.3.8 Lightning Sensor Systems: Stormscopes
4.3.9 Optical Radar
4.3.9.1 Doppler Lidar
4.3.9.2 Infrared Locators and Radiometers
4.3.10 The Integrated Localization of Dangerous Phenomena
4.4 Collision Avoidance Sensors
4.4.1 Traffic Alert and Collision Avoidance Systems (TCAS)
4.4.1.1 The Purpose
4.4.1.2 A Short History
4.4.1.3 TCAS Levels of Capability
4.4.1.4 TCAS Concepts and Principles of Operation
4.4.1.5 Basic Components
4.4.1.6 Operation
4.4.1.7 TCAS Logistics
4.4.1.8 Cockpit Presentation
4.4.1.9 Examples of System Implementation
4.4.2 The Ground Proximity Warning System (GPWS)
4.4.2.1 Purpose and Necessity
4.4.2.2 GPWS History, Principles, and Evolution
4.4.2.3 GPWS Modes
4.4.2.4 Shortcomings of Classical GPWS
4.4.2.5 Enhanced GPWSs
4.4.2.6 Look—Ahead Warnings
4.4.2.7 Implementation Examples
References
……
5 DEVICES AND SENSORS FOR LINEAR ACCELERATION MEASUREMENT
6 GYROSCOPIC DEVICES AND SENSORS
7 COMPASSES
8 PROPULSION SENSORS
9 PRINCIPLES AND EXAMPLES OF SENSORINTEGRATION
EPILOGUE
INDEX



SERIES PREFACE
PREFACE
ACKNOWLEDGMENTS
ABOUT THE SERIES EDITOR
ABOUT THE EDITOR
1 INTRODUCTION
1.1 General Considerations
1.1.1 Types of Aerospace Vehicles and Missions
1.1.2 The Role of Sensors and Control Systems in Aerospace
1.1.3 Specific Design Criteria for Aerospace Vehicles and their Sensors
1.1.4 Physical Principles Influencing Primary Aerospace Sensor Design
1.1.5 Reference Frames Accepted in Aviation and Astronautics
1.2 Characteristics and Challenges of the Atmospheric Environment
1.2.1 Components of the Earth's Atmosphere
1.2.2 Stationary Models of the Atmosphere
1.2.3 Anisotropy and Variability in the Atmosphere
1.2.4 Electrical Charges in the Atmosphere
1.2.5 Electromagnetic Wave Propagation in the Atmosphere
1.2.6 Geomagnetism
1.2.7 The Planetary Atmosphere
1.3 Characteristics and Challenges of the Space Environment
1.3.1 General Considerations
1.3.2 Near—Earth Space
1.3.3 Circumsolar (Near—Sun) Space
1.3.4 Matter in Space
1.3.5 Distances and Time Scales in Deep Space
References
2 AIR PRESSURE—DEPENDENT SENSORS
2.1 Basic Aircraft Instrumentation
2.2 Fundamental Physical Properties of Airflow
2.2.1 Fundamental Airflow Physical Property Definitions
2.2.1.1 Pressure
2.2.1.2 Air Density
2.2.1.3 Temperature
2.2.1.4 Flow Velocity
2.2.2 The Equation of State for a Perfect Gas
2.2.3 Extension o fDefinitions: Total, Dynamic, Static, and Stagnation
2.2.4 The Speed of Sound and Mach Number
2.2.4.1 The Speed of Sound
2.2.4.2 Mach Number and Compressibility
2.2.5 The Source of Aerodynamic Forces
2.3 Altitude Conventions
2.4 Barometric Altimeters
2.4.1 Theoretical Considerations
2.4.1.1 The Troposphere
2.4.1.2 The Stratosphere
2.4.2 Barometric Altimeter Principles and Construction
2.4.3 Barometric Altimeter Errors
2.4.3.1 Methodical Errors
2.4.3.2 Instrumental Errors
2.5 Airspeed Conventions
2.6 The Manometric Airspeedlndicator
2.6.1 Manometric Airspeedlndicator Principles and Construction
2.6.2 Theoretical Considerations
2.6.2.1 Subsonic Incompressible Operation
2.6.2.2 Subsonic Compressible Operation
2.6.2.3 Supersonic Operation
2.6.3 Manometric Airspeed Indicator Errors
2.6.3.1 Methodical Errors
2.6.3.2 Instrumental Errors
2.7 The Vertical Speed Indicator (VSI)
2.7.1 VSI Principles and Construction
2.7.2 Theoretical Considerations
2.7.2.1 Lag Rate (Time Constant)
2.7.2.2 Sensitivity to Mach Number
2.7.2.3 Sensitivity to Altitude
2.7.3 VSI Errors
2.8 Angles of Attack and Slip
2.8.1 The Pivoted Vane
2.8.2 The Differential Pressure Tube
2.8.3 The Null—Seeking Pressure Tube
References
Appendix
3 RADAR ALTIMETERS
3.1 Introduction
3.1.1 Definitions
3.1.2 Altimetry Methods
3.1.3 General Principles of Radar Altimetry
3.1.4 Classification by Different Features
3.1.5 Application and Performance Characteristics
3.1.5.1 Aircraft Applications
3.1.5.2 Spacecraft Applications
3.1.5.3 Military Applications
3.1.5.4 Remote Sensing Applications
3.1.6 Performance Characteristics
3.2 Pulse Radar Altimeters
3.2.1 Principle of Operation
3.2.2 Pulse Duration
3.2.3 Tracking Altimeters
3.2.4 Design Principles
3.2.5 Features of Altimeters with Pulse Compression
3.2.6 Pulse Laser Altimetry
3.2.7 Some Examples
3.2.8 Validation
3.2.9 Future Trends
3.3 Continuous Wave Radar Altimeters
3.3.1 Principles of Continuous Wave Radar
3.3.2 FMCW Radar Waveforms
3.3.3 Design Principles and Structural Features
3.3.3.1 Local Oscillator Automatic Tuning
3.3.3.2 Single—Sideband Receiver Structure
3.3.4 The Doppler Effect
3.3.5 Alternative Measuring Devices for FMCW Altimeters
3.3.6 Accuracy and Unambiguous Altitude
3.3.7 Aviation Applications
3.4 Phase Precise Radar Altimeters
3.4.1 The Phase Method of Range Measurement
3.4.2 The Two—Frequency Phase Method
3.4.3 Ambiguity and Accuracy in the Two—Frequency Method
3.4.4 Phase Ambiguity Resolution
3.4.5 Waveforms
3.4.6 Measuring Devices and Signal Processing
3.4.7 Remarks on the Accuracy of CW and Pulse Radar Altimeters
3.5 Radioactive Altimeters for Space Application
3.5.1 Motivation and History
3.5.2 Physical Bases
3.5.2.1 Features of Radiation
3.5.2.2 Generators of Photon Emission
3.5.2.3 Receivers
3.5.2.4 Propagation Features
3.5.3 Principles of Operation
3.5.4 Radiation Dosage
3,5.5 Examples of Radioisotope Altimeters
References
4 AUTONOMOUS RADIO SENSORS FOR MOTION PARAMETERS
4.1 Introduction
4.2 Doppler Sensors for Ground Speed and Crab Angle
4.2.1 Physical Basis and Functions
4.2.2 Principle of Operation
4.2.3 Classification and Features of Sensors for Ground Speed and Crab Angle
4.2.4 Generalized Structural Diagram for the Ground Speed'and Crab Angle Meter
4.2.5 Design Principles
4.2.6 Sources of Doppler Radar Errors
4.2.7 Examples
4.3 Airborne Weather Sensors
4.3.1 Weather Radar as Mandatory Equipment of Airliners and Transport Aircraft
4.3.2 Multifunctionality of Airborne Weather Radar
4.3.3 Meteorological Functions of AWR
4.3.4 Principles ofDWP Detection with AWR
4.3.4.1 Developing Methods of DWP Detection
4.3.4.2 Cumulonimbus Clouds and Heavy Rain
4.3.4.3 Turbulence Detection
4.3.4.4 Wind Shear Detection
4.3.4.5 Hail Zone Detection
4.3.4.6 Probable Icing—in—flight Zone Detection
4.3.5 Surface Mapping
4.3.5.1 Comparison of Radar and Visual Orientation
4.3.5.2 The Surface—Mapping Principle
4.3.5.3 Reflecting Behavior ofthe Earth's Surface
4.3.5.4 The Radar Equation and Signal Correction
4.3.5.5 Automatic Classification of Navigational Landmarks
4.3.6 AWR Design Principles
4.3.6.1 The Operating Principle and Typical Structure of AWR
4.3.6.2 AWR Structures
4.3.6.3 Performance Characteristics: Basic Requirements
4.3.7 AWR Examples
4.3.8 Lightning Sensor Systems: Stormscopes
4.3.9 Optical Radar
4.3.9.1 Doppler Lidar
4.3.9.2 Infrared Locators and Radiometers
4.3.10 The Integrated Localization of Dangerous Phenomena
4.4 Collision Avoidance Sensors
4.4.1 Traffic Alert and Collision Avoidance Systems (TCAS)
4.4.1.1 The Purpose
4.4.1.2 A Short History
4.4.1.3 TCAS Levels of Capability
4.4.1.4 TCAS Concepts and Principles of Operation
4.4.1.5 Basic Components
4.4.1.6 Operation
4.4.1.7 TCAS Logistics
4.4.1.8 Cockpit Presentation
4.4.1.9 Examples of System Implementation
4.4.2 The Ground Proximity Warning System (GPWS)
4.4.2.1 Purpose and Necessity
4.4.2.2 GPWS History, Principles, and Evolution
4.4.2.3 GPWS Modes
4.4.2.4 Shortcomings of Classical GPWS
4.4.2.5 Enhanced GPWSs
4.4.2.6 Look—Ahead Warnings
4.4.2.7 Implementation Examples
References
……
5 DEVICES AND SENSORS FOR LINEAR ACCELERATION MEASUREMENT
6 GYROSCOPIC DEVICES AND SENSORS
7 COMPASSES
8 PROPULSION SENSORS
9 PRINCIPLES AND EXAMPLES OF SENSORINTEGRATION
EPILOGUE
INDEX



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