ALBERT

Note: Contents 1. Introductory Remarks on Remote Sensing / E. SCHANDA 1.1 Application Areas of Remote Sensing 1.2 Sensing Systems 1.3 Remote Sensing and Spectral Constraints 2. Aerospace Photography / A. E. SALERNO 2.1 Introduction 2.2 Characteristics of Photographic Process 2.2.1 Sensitometry General 2.2.2 The Characteristic Curve 2.2.3 Development Control 2.2.4 Exposure Control 2.2.5 Film Speed 2.2.6 Reciprocity Law Anomalies 2.2.7 Density Measurement 2.2.8 Measurement of Color 2.2.9 Tone Reproduction Theory 2.2.10 Spectral Sensitivity 2.2.11 Resolution 2.2.12 Granularity 2.2.13 Dimensional Stability and Mechanical Properties 2.3 Cameras and Films 2.3.1 Cameras (General) 2.3.2 Aerial Cameras — Common Features 2.3.3 Optical System 2.3.4 Calibration 2.3.5 Image Motion 2.3.6 Hand Held Cameras 2.3.7 Special Cameras 2.3.8 Film (General) 2.3.9 Aerial Photographic Materials 2.3.10 Black-and-White Camera Films 2.3.11 Color Camera Films 2.4 Photographic Attributes of Earth Sciences 2.4.1 Agriculture 2.4.2 Geography and Geology 2.4.3 Hydrology and Oceanography 2.4.4 Anomalies, Atmospheric 2.4.5 Factors Affecting the Photo Image 2.4.6 Image Formation on Color Film 2.4.7 Processing of Color Film 2.4.8 Photo Systems, Choice 2.4.9 Image Enhancement Procedure Bibliography 3. Infrared Sensing Methods / P. W. SCHAPER 3.1 Introduction 3.2 The Infrared Radiation Field 3.3 Fundamentals of Measurement 3.4 Methods of Measurement 3.4.1 The Single Element Radiometer 3.4.2 Imaging Radiometers 3.4.3 Multi Wavelength Channel Radiometers 3.4.4 Spectrometers 3.4.5 Interferometers 3.5 Applications 3.6 Data Interpretation Error Sources 3.7 Expectations of the Near Future References 4. Laser Applications in Remote Sensing / R.T.H. COLLIS and P. B. RUSSELL 4.1 Introduction 4.1.1 Scope and Definitions 4.1.2 Technical Approaches 4.2 Fundamentals of Physical Processes Involved 4.2.1 Specular Reflection and Elastic (Non-resonant) Scattering 4.2.2 Inelastic and Resonant Scattering 4.2.3 Resonant Absorption 4.2.4 Doppler Effects 4.2.5 Polarization 4.3 Instrumentation 4.3.1 System Concepts 4.3.2 System Configuration 4.3.3 Lasers 4.3.4 Photodetection 4.3.5 Eye Safety 4.3.6 Viewpoint of Remote Sensing 4.4 Applications 4.4.1 General 4.4.2 Backscattering Techniques - Non-resonant Elastic Scattering 4.4.3 Inelastic and Resonant Backscattering 4.4.4 Resonant Absorption 4.4.5 Doppler Techniques 4.4.6 Polarization References 5. Radar Methods / G.P. DE LOOR 5.1 General Aspects 5.1.1 Introduction 5.1.2 Resolution 5.1.3 Image Build-up; Flight Procedure 5.1.4 Parallax 5.1.5 Image Correction 5.1.6 Registration of the Radar Signals 5.2 Backgrounds 5.2.1 Introduction 5.2.2 The Radar Equation 5.2.3 Ground Returns 5.3 Applications 5.3.1 Introduction 5.3.2 Geography 5.3.3 Geology 5.3.4 Vegetation Studies 5.3.5 Sea, Coastal and Oceanographic Studies 5.4 Conclusion References 6. Passive Microwave Sensing / E. SCHANDA 6.1 Principles of Passive Microwave Remote Sensing 6.1.1 Physical Fundamentals of Microwave Radiometry 6.1.2 Semitransparent Media 6.1.3 The Effects of the Atmosphere 6.2 Instrumental Aspects of Microwave Radiometry 6.2.1 The Sensitivity of a Microwave Radiometer 6.2.2 Other Types of Radiometers 6.2.3 Angular Resolution and Range of Passive Microwave Sensing 6.2.4 Realisations of Microwave Radiometers 6.3 Emissive Properties of Materials on the Surface of the Earth 6.3.1 Plane Surfaces of Homogeneous Materials 6.3.2 Heterogeneous Media 6.3.3 Rough Surfaces 6.3.4 Various Investigations on Emissivities 6.4 Remote Determination of Atmospheric Constituents by Their Micro-wave Spectra 6.4.1 The Absorption Coefficients of the Line Spectra 6.4.2 Determinations of Height Profiles 6.5 Passive Microwave Remote Sensing of Water, Ice and Snow 6.5.1 Investigations of Water Surfaces 6.5.2 Investigations of Ice and Snow 6.6 Investigations of the Soil, Vegetation and Geological Features 6.7 Investigations of the Atmosphere and of Meteorological Features 6.7.1 Sounding of Atmospheric Constituents from Molecular Line Radiation 6.7.2 Observation of Meteorological Features References 7. Applications of Gamma Radiation in Remote Sensing / R.L. GRASTY 7.1 The Natural Gamma-radiation Field 7.2 Gamma-ray Detector Systems 7.3 Operational Procedures 7.3.1 Background Radiation 7.3.2 Height Correction 7.3.3 Calibration and Spectral Stripping 7.4 Applications 7.4.1 Mineral Exploration 7.4.2 Geological Mapping 7.4.3 Water-equivalent Snow Measurements 7.4.4 Soil Moisture Measurement 7.4.5 Monitoring Nuclear Facilities 7.5 Future Prospects References 8. Sonar Methods / D.J. CREASEY 8.1 Introduction 8.2 Propagation of Acoustic Energy 8.2.1 General 8.2.2 Absorption Losses in Water 8.2.3 Beam Bending in Water 8.2.4 Propagation in Air 8.3 The Sonar Equation 8.3.1 Transducers and Arrays 8.3.2 Noise and Reverberation 8.3.3 Signal to Noise Ratio and Signal to Reverberation Ratio 8.3.4 Interference Signals in Air 8.4 Factors Affecting Resolution in a Sonar System 8.4.1 General 8.4.2 Range Resolution 8.4.3 Bearing Resolution 8.4.4 Doppler Effect in Sonar 8.5 Applications 8.5.1 Echo Sounding 8.5.2 Sonars with Fixed Beams 8.5.3 Mechanically Rotated Sonar Array Systems 8.5.4 Side-scan Sonars 8.5.5 Sub-bottom Profiling Systems 8.5.6 Sonars with Sectors Scanned Electronically 8.5.7 Remote Sensing Application of Sonar in Air References 9. Digital Picture Processing / PH. HARTL 9.1 Introduction 9.1.1 General Remarks 9.1.2 Relation between Image and Real Scene 9.1.3 Enhancement and Filtering 9.2 The Elements of an Image Data Processing and Analysis System 9.2.1 Data Acquisition Subsystem 9.2.2 Data Handling Subsystem 9.2.3 Data Preprocessing Subsystem 9.2.4 Data Storage and Retrieval Subsystem 9.3 Geometric Corrections 9.3.1 Linear Transformations 9.3.2 Quadratic and Higher Order Transformations 9.3.3 Reference Marks 9.3.4 Image Gridding 9.3.5 Image Registration 9.3.6 Geometric Correction Concepts 9.4 Image Enhancement and Filtering Processes 9.4.1 Enhancement Processes 9.4.2 Image Smoothing 9.4.3 Image Sharpening 9.4.4 Matched Filters 9.4.5 Ratio Mapping and Generalization of Image Combination Procedures 9.4.6 Pseudocolor Transformation 9.5 Feature Extraction and Classification 9.5.1 Spectral Features 9.5.2 Spatial Features 9.5.3 The Decision Process 9.5.4 The Decision Criteria 9.5.5 Unsupervised Classification 9.5.6 Recognizing of Bridges, Rivers, Lakes, and Islands 9.6 Appendix 1: The Image Signal in Spatial and Frequency Domain 9.6.1 Signals in the Spatial Domain 9.6.2 Signals in the Frequency Domain 9.7 Appendix 2: Numerical Example for Texture-context Features References Subject Index Color Plates

Note: Contents 1 Some Basic Relations 1.1 Natural Parameters and Observables 1.2 Propagation of Electromagnetic Waves 1.3 Waves at Boundaries Between Different Media 2 Spectral Lines of Atmospheric Gases 2.1 Resonant Frequencies of Molecules 2.2 Widths of Spectral Lines 2.3 Applications to the Earth's Atmosphere 3 Spectral Properties of Condensed Matter 3.1 Elementary Theory of Organic Dyes 3.2 Chlorophyll and Spectral Properties of Plants 3.3 Polarization of the Media and Dispersion of Radiation 4 Scattering of Radiation 4.1 Light Scattering by Molecules 4.2 Scattering of Radiation by Macroscopic Particles 4.3 Backscattering from Rough Surfaces 5 Transport of Radiation 5.1 The Equation of Radiative Transfer 5.2 Kirchhoff's Law and Radiometry 5.3 Radiometric Observation of Atmospheric Parameters and the Inversion of Remotely Sensed Data References Subject Index

Note: Contents Chapter One STATISTICAL DESCRIPTION OF TURBULENCE 1.1 Turbulence as a Random Process 1.2 Statistical Averages of Random Variables 1.3 Stationarity and Homogeneity 1.4 Spectral Decomposition 1.5 Connection Between Correlation and Spectral Functions 1.6 The Equations of Turbulences Chapter Two rlliASUREMENT OF TURBULENT FLUCTUATIONS 2.1 Modeling of Statistical Characteristics of Turbulent Fluctuations 2.2 Experimental Systems 2.3 Thermo-anemometry (Hot-wire and Hot-film) 2.4 Doppler method 2.5 Other Methods of Measuring Turbulent Fluctuations 2.6 Instrumental Processing of Recorded Fluctuations 2.7 Experimental Uncertainties Chapter Three TRANSDUCERS OF FINITE SIZE IN TURBULENT FLUCTUATIONS 3.1 General Relationships 3.2 Spatial and Wave Characteristics of Simple Transducers 3.3 A System of Transducers as Frequency Filter 3.4 Correction Functions for a Field of Velocity Fluctuations Chapter Four STATISTICAL MODELS OF TURBULENT FIELDS 4.1 Models of the Field as a Basis for Correcting the Results of Measurements 4.2 Corcos Model of the Turbulent Pressure Field and Its Simplest Modifications 4.3 Departure from Multiplication Hypothesis 4.4 Diffusion Model 4.5 Convection Model 4.6 Phase Velocity of Cross-Spectrum Chapter Five CORRECTION FUNCTIONS FOR THE PRESSURE FLUCTUATION FIELD 5.1 Power Spectrum 5.2 The Cross-Spectrum 5.3 Measurements with Wave Filters REFERENCES SUBJECT INDEX , Aus dem Russischen übersetzt