Kooperativer Bibliotheksverbund

UID:

Format: xvii, 534 Seiten : , Illustrationen, Diagramme, Karten (teilweise farbig).

Edition: Third edition

ISBN: 978-1-119-52301-7

Series Statement: Wiley series in remote sensing

Additional Edition: Erscheint auch als Online-Ausgabe ISBN 9781119523048

Language: English

Subjects: Geography

Keywords: Atmosphäre ; Fernerkundung ; Wellenausbreitung

URL: Inhaltsverzeichnis

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Format: 1 online resource (xix, 288 pages, 24 unnumbered pages of plates) : , illustrations (some color)

ISBN: 9781118116104 , 1118116100 , 1118116070 , 9781118116074 , 9781118116098 , 1118116097 , 9781118116081 , 1118116089 , 1282242571 , 9781282242579

Series Statement: JPL space science and technology series

Content: "This book describes the application of polarimetric synthetic aperture radar to Earth remote sensing based on research at the NASA Jet Propulsion Laboratory (JPL). This book synthesizes all current research to provide practical information for both the newcomer and the expert in radar polarimetry. The text offers a concise description of the mathematical fundamentals illustrated with many examples using SAR data, with a main focus on remote sensing of the Earth. The book begins with basics of synthetic aperture radar to provide the basis for understanding how polarimetric SAR images are formed and gives an introduction to the fundamentals of radar polarimetry. It goes on to discuss more advanced polarimetric concepts that allow one to infer more information about the terrain being imaged. In order to analyze data quantitatively, the signals must be calibrated carefully, which the book addresses in a chapter summarizing the basic calibration algorithms. The book concludes with examples of applying polarimetric analysis to scattering from rough surfaces, to infer soil moisture from radar signals"--

Note: Frontmatter -- Color Plates -- Synthetic Aperture Radar (SAR) Imaging Basics -- Basic Principles of SAR Polarimetry -- Advanced Polarimetric Concepts -- Polarimetric SAR Calibration -- Applications: Measurement of Surface Soil Moisture -- Appendix A: Tilted Small-Perturbation Model Details -- Appendix B: Bistatic Scattering Matrix of a Cylinder with Arbitrary Orientation -- Appendix C: Nomenclature -- Index.

Additional Edition: Print version: Van Zyl, Jakob, 1967- Synthetic aperture radar polarimetry. Hoboken, NJ : Wiley, 2011 ISBN 9781118115114

Language: English

Keywords: Electronic books. ; Electronic books. ; Electronic books.

URL: https://onlinelibrary.wiley.com/doi/book/10.1002/9781118116104

URL: https://onlinelibrary.wiley.com/doi/book/10.1002/9781118116104

URL: https://onlinelibrary.wiley.com/doi/book/10.1002/9781118116104

UID:

Format: 1 online resource (555 p.).

Edition: 3rd ed.

ISBN: 9781119523048 , 1119523044 , 9781119523123 , 1119523125

Series Statement: Wiley Series in Remote Sensing and Image Processing Ser.

Note: Description based upon print version of record. , 4.4.2 Effect of Surface Cover. , Cover -- Title Page -- Copyright Page -- Contents -- Preface -- Chapter 1 Introduction -- 1.1 Types and Classes of Remote Sensing Data -- 1.2 Brief History of Remote Sensing -- 1.3 Remote Sensing Space Platforms -- 1.4 Transmission Through the Earth and Planetary Atmospheres -- References and Further Reading -- Chapter 2 Nature and Properties of Electromagnetic Waves -- 2.1 Fundamental Properties of Electromagnetic Waves -- 2.1.1 Electromagnetic Spectrum -- 2.1.2 Maxwellś Equations -- 2.1.3 Wave Equation and Solution -- 2.1.4 Quantum Properties of Electromagnetic Radiation , 2.1.5 Polarization -- 2.1.6 Coherency -- 2.1.7 Group and Phase Velocity -- 2.1.8 Doppler Effect -- 2.2 Nomenclature and Definition of Radiation Quantities -- 2.2.1 Radiation Quantities -- 2.2.2 Spectral Quantities -- 2.2.3 Luminous Quantities -- 2.3 Generation of Electromagnetic Radiation -- 2.4 Detection of Electromagnetic Radiation -- 2.5 Interaction of Electromagnetic Waves with Matter: Quick Overview -- 2.6 Interaction Mechanisms Throughout the Electromagnetic Spectrum -- Exercises -- References and Further Reading -- Chapter 3 Solid Surfaces Sensing in the Visible and Near Infrared , 3.1 Source Spectral Characteristics -- 3.2 Wave-Surface Interaction Mechanisms -- 3.2.1 Reflection, Transmission, and Scattering -- 3.2.2 Vibrational Processes -- 3.2.3 Electronic Processes -- 3.2.4 Fluorescence -- 3.3 Signature of Solid Surface Materials -- 3.3.1 Signature of Geologic Materials -- 3.3.2 Signature of Biologic Materials -- 3.3.3 Depth of Penetration -- 3.4 Passive Imaging Sensors -- 3.4.1 Imaging Basics -- 3.4.2 Sensor Elements -- 3.4.3 Detectors -- 3.5 Types of Imaging Systems -- 3.6 Description of Some Visible/Infrared Imaging Sensors , 3.6.1 Landsat Enhanced Thematic Mapper Plus (ETM+) -- 3.6.2 Advanced Spaceborne Thermal Emission and Reflection Radiometer (ASTER) -- 3.6.3 Mars Orbiter Camera (MOC) -- 3.6.4 Mars Exploration Rover Panchromatic Camera (Pancam) -- 3.6.5 Cassini Imaging Instrument -- 3.6.6 Juno Imaging System -- 3.6.7 Europa Imaging System -- 3.6.8 Cassini Visual and Infrared Mapping Spectrometer (VIMS) -- 3.6.9 Chandrayaan Imaging Spectrometer M3 -- 3.6.10 Sentinel Multispectral Imager -- 3.6.11 Airborne Visible-Infrared Imaging Spectrometer (AVIRIS) -- 3.7 Active Sensors , 3.8 Surface Sensing at Very Short Wavelengths -- 3.8.1 Radiation Sources -- 3.8.2 Detection -- 3.9 Image Data Analysis -- 3.9.1 Detection and Delineation -- 3.9.2 Classification -- 3.9.3 Identification -- Exercises -- References and Further Reading -- Chapter 4 Solid-Surface Sensing: Thermal Infrared -- 4.1 Thermal Radiation Laws -- 4.1.1 Emissivity of Natural Terrain -- 4.1.2 Emissivity from the Sun and Planetary Surfaces -- 4.2 Heat Conduction Theory -- 4.3 Effect of Periodic Heating -- 4.4 Use of Thermal Emission in Surface Remote Sensing -- 4.4.1 Surface Heating by the Sun

Additional Edition: Print version: Elachi, Charles Introduction to the Physics and Techniques of Remote Sensing Newark : John Wiley & Sons, Incorporated,c2021 ISBN 9781119523017

Language: English

Keywords: Electronic books. ; Electronic books. ; Electronic books.

URL: https://onlinelibrary.wiley.com/doi/book/10.1002/9781119523048

URL: https://onlinelibrary.wiley.com/doi/book/10.1002/9781119523048

URL: https://onlinelibrary.wiley.com/doi/book/10.1002/9781119523048

UID:

Format: XVII, 552 S. , Ill., graph. Darst., Kt.

Edition: 2. ed.

ISBN: 0471475696 , 9780471475699

Series Statement: Wiley series in remote sensing

Note: Includes bibliographical references and index

Language: English

Subjects: Geography

Keywords: Fernerkundung ; Ionosphäre ; Atmosphäre ; Wellenausbreitung

URL: Publisher description

URL: Table of contents only

UID:

Format: 1 online resource (555 pages) : , illustrations

Edition: Third edition.

ISBN: 9781119523123

Additional Edition: Print version: Elachi, Charles. Introduction to the physics and techniques of remote sensing. Hoboken, New Jersey : John Wiley & Sons, Incorporated, c2021 ISBN 9781119523017

Language: English

Keywords: Electronic books.

URL: Click to View

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Format: 1 Online-Ressource (1.014 Seiten) , Illustrationen

ISBN: 9781630810504 (e-book)

Note: CONTENTS Preface Photo Credits Computer Codes 1 Introduction 1-1 Why Microwaves for Remote Sensing? 1-2 A Brief Overview of Microwave Sensors 1-3 A Short History of Microwave Remote Sensing 1-3.1 Radar 1-3.2 Radiometers 1-4 The Electromagnetic Spectrum 1-5 Basic Operation and Applications of Radar 1-5.1 Operation of Remote-Sensing Radars 1-5.2 Applications of Remote-Sensing Radars 1-6 Basic Operation and Applications of Radiometers 1-6.1 Radiometer Operation 1-6.2 Applications of Microwave Radiometry 1-7 Image Examples 2 Electromagnetic Wave Propagation 2-1 EM Plane Waves 2-1.1 Constitutive Parameters 2-1.2 Maxwell's Equations 2-1.3 Complex Permittivity 2-1.4 Wave Equations 2-2 Plane-Wave Propagation in Lossless Media 2-2.1 Uniform Plane Waves 2-2.2 General Relation between E and H 2-3 Wave Polarization in a Lossless Medium 2-3.1 Linear Polarization 2-3.2 Circular Polarization 2-3.3 Elliptical Polarization 2-4 Plane Wave Propagation in Lossy Media 2-4.1 Low Loss Dielectric 2-4.2 Good Conductor 2-5 Electromagnetic Power Density 2-5.1 Plane Wave in a Lossless Medium 2-5.2 Plane Wave in a Lossy Medium 2-5.3 Decibel Scale tor Power Ratios 2-6 Wave Reflection and Transmission at Normal Incidence 2-6.1 Boundary between Lossless Media 2-6.2 Boundary between Lossy Media 2-7 Wave Reflection and Transmission at Oblique Incidence 2-7.1 Horizontal Polarization—Lossless Media 2-7.2 Vertical Polarization 2-8 Reflectivity and Transmissivity 2-9 Oblique Incidence onto a Lossy Medium 2- 10 Oblique Incidence onto a Two-Layer Composite 2-10.1 Input Parameters 2-10.2 Propagation Matrix Method 2-10.3 Multiple Reflection Method 3 Remote-Sensing Antennas 3-1 The Hertzian Dipole 3-2 Antenna Radiation Characteristics 3-2.1 Antenna Pattern 3-2.2 Beam Dimensions 3-2.3 Antenna Directivity 3-2.4 Antenna Gain 3-2.5 Radiation Efficiency 3-2.6 Effective Area of a Receiving Antenna 3-3 Friis Transmission Formula 3-4 Radiation by Large-Aperture Antennas 3-5 Rectangular Aperture with Uniform Field Distribution 3-5.1 Antenna Pattern in x-y Plane 3-5.2 Beamwidth 3-5.3 Directivity and Effective Area 3-6 Circular Aperture with Uniform Field Illumination 3-7 Nonuniform-Amplitude Illumination 3-8 Beam Efficiency 3-9 Antenna Arrays 3-10 N-Element Array with Uniform Phase Distribution 3-10.1 Uniform Amplitude Distribution 3-10.2 Grating Lobes 3-10.3 Binomial Distribution 3-11 Electronic Scanning of Arrays 3-12 Antenna Types 3-12.1 Horn Antennas 3-12.2 Slot Antennas 3-12.3 Microstrip Antennas 3-13 Active Antennas 3-13.1 Advantages of Active Antennas 3-13.2 Digital Beamforming with Active Antennas 4 Microwave Dielectric Properties of Natural Earth Materials 4-1 Pure-Water Single-Debye Dielectric Model (f 〈 50 GHz) 4-2 Saline-Water Double-Debye Dielectric Model (f〈 1000 GHz) 4-3 Dielectric Constant of Pure Ice 4-4 Dielectric Mixing Models for Heterogeneous Materials 4-4.1 Randomly Oriented Ellipsoidal Inclusions 4-4.2 Polder-van Santen/de Loor Formulas 4-4.3 Tinga-Voss-Blossey (TVB) Formulas 4-4.4 Other Dielectric Mixing Formulas 4-5 Sea Ice 4-5.1 Dielectric Constant of Brine 4-5.2 Brine Volume Fraction 4-5.3 Dielectric Properties 4-6 Dielectric Constant of Snow 4-6.1 Dry Snow 4-6.2 Wet Snow 4-7 Dielectric Constant of Dry Rocks 4-7.1 Powdered Rocks 4-7.2 Solid Rocks 4-8 Dielectric Constant of Soils 4-8.1 Dry Soil 4-8.2 Wet Soil 4-8.3 εsoil in 0.3-1.5 GHz Band 4-9 Dielectric Constant of Vegetation 4-9.1 Dielectric Constant of Canopy Constituents 4-9.2 Dielectric Model 5 Radar Scattering 5-1 Wave Polarization in a Spherical Coordinate System 5-2 Scattering Coordinate Systems 5-2.1 Forward Scattering Alignment (FSA) Convention 5-2.2 Backscatter Alignment (BSA) Convention 5-3 Scattering Matrix 5-3.1 FSA Convention 5-3.2 BSA Convention 5-3.3 Stokes Parameters and Mueller Matrix 5-4 Radar Equation 5-5 Scattering from Distributed Targets 5-5.1 Narrow-Beam Scatterometer 5-5.2 Imaging Radar 5-5.3 Specific Intensities for Distributed Target 5-6 RCS Statistics 5-7 Rayleigh Fading Model 5-7.1 Underlying Assumptions 5-7.2 Linear Detection 5-7.3 Square-Law Detection 5-7.4 Interpretation 5-8 Multiple Independent Samples 5-8.1 N-Look Amplitude Image 5-8.2 N-Look Intensity Image 5-8.3 N-Look Square-Root Intensity Image 5-8.4 Spatial Resolution vs. Radiometric Resolution 5-8.5 Applicability of the Rayleigh Fading Model 5-9 Image Texture and Despeckle Filtering . 5-9.1 Image Texture 5-9.2 Despeckling Filters 5-10 Coherent and Noncoherent Scattering 5-10.1 Surface Roughness 5-10.2 Bistatic Scattering 5-10.3 Specular Reflectivity 5-10.4 Bistatic-Scattering Coefficient 5-10.5 Backscattering Response of a Smooth Surface 5-11 Polarization Synthesis 5-11.1 RCS Polarization Response 5-11.2 Distributed Targets 5-11.3 Mueller Matrix Approach 5-12 Polarimetric Scattering Statistics 5-13 Polarimetric Analysis Tools 5-13.1 Scattering Covariance Matrix 5-13.2 Eigenvector Decomposition 5-13.3 Useful Polarimetric Parameters 5-13.4 Image Examples 5-13.5 Freeman-Durden Decomposition 6 Microwave Radiometry and Radiative Transfer 6-1 Radiometric Quantities 6-2 Thermal Radiation 6-2.1 Quantum Theory of Radiation 6-2.2 Planck's Blackbody Radiation Law 6-2.3 The Rayleigh-Jeans Law 6-3 Power-Temperature Correspondence 6-4 Radiation by Natural Materials 6-4.1 Brightness Temperature 6-4.2 Brightness Temperature Distribution 6-4.3 Antenna Temperature 6-5 Antenna Efficiency Considerations 6-5.1 Beam Efficiency 6-5.2 Radiation Efficiency 6-5.3 Radiometer Measurement Ambiguity 6-6 Theory of Radiative Transfer 6-6.1 Equation of Radiative Transfer 6-6.2 Brightness-Temperature Equation 6-6.3 Brightness Temperature of a Stratified Medium 6-6.4 Brightness Temperature of a Scatter-Free Medium 6-6.5 Upwelling and Downwelling Atmospheric Brightness Temperatures 6-7 Terrain Brightness Temperature 6-7.1 Brightness Transmission Across a Specular Boundary 6-7.2 Emission by a Specular Surface 6-7.3 Emissivity of a Rough Surface 6-7.4 Extreme Surface Conditions 6-7.5 Emissivity of a Two-Layer Composite 6-8 Downward-Looking Satellite Radiometer 6-9 Polarimetric Radiometry 6-10 Stokes Parameters and Periodic Structures 7 Microwave Radiometric Systems 7-1 Equivalent Noise Temperature 7-2 Characterization of Noise 7-2.1 Noise Figure 7-2.2 Equivalent Input Noise Temperature 7-2.3 Noise Temperature of a Cascaded System 7-2.4 Noise Temperature of a Lossy Two-Port Device 7-3 Receiver and System Noise Temperatures 7-3.1 Receiver Alone 7-3.2 Total System Including Antenna 7-4 Radiometer Operation 7-4.1 Measurement Accuracy 7-4.2 Total-Power Radiometer 7-4.3 Radiometric Resolution 7-5 Effects of Receiver Gain Variations 7-6 Dicke Radiometer 7-7 Balancing Techniques 7-7.1 Reference-Channel Control Method 7-7.2 Antenna-Channel Noise-Injection Method 7-7.3 Pulsed Noise-Injection Method 7-7.4 Gain-Modulation Method 7-8 Automatic-Gain-Control (AGC) Techniques 7-9 Noise-Adding Radiometer 7-10 Summary of Radiometer Properties 7-11 Radiometer Calibration Techniques 7-11.1 Receiver Calibration 7-11.2 Calibration Sources 7-11.3 Effects of Impedance Mismatches 7-11.4 Antenna Calibration 7-11.5 Cryoload Technique 7-11.6 Bucket Technique 7-12 Imaging Considerations 7-12.1 Scanning Configurations 7-12.2 Radiometer Uncertainty Principle 7-13 Interferometric Aperture Synthesis 7-13.1 Image Reconstruction 7-13.2 MIR Radiometric Sensitivity 7-14 Polarimetric Radiometer 7-14.1 Coherent Detection 7-14.2 Incoherent Detection 7-15 Calibration of Polarimetric Radiometers 7-15.1 Forward Model for a Fully Polarimetric Radiometer 7-15.2 Forward Model for the Polarimetric Calibration Source 7-15.3 Calibration by Inversion of the Forward Models 7-16 Digital Radiometers 8 Microwave Interaction with Atmospheric Constituents 8-1 Standard Atmosphere 8-1.1 Atmospheric Composition 8-1.2 Temperature Profile 8-1.3 Density Profile 8-1.4 Pressure Profi

Additional Edition: Druckausgabe Ulaby, Fawwaz T. Microwave radar and radiometric remote sensing. Ann Arbor, [Michigan] : The University of Michigan Press, c2014 ISBN 9780472119356

Language: English

Keywords: Electronic books

URL: Fulltext @ Ebook Central (AWI only)

URL: Table of Contents

UID:

Format: xix, 288 p., [24] p. of plates : , ill. (chiefly col.).

Edition: 1st ed.

Edition: Electronic reproduction. Ann Arbor, MI : ProQuest, 2015. Available via World Wide Web. Access may be limited to ProQuest affiliated libraries.

Series Statement: JPL space science and technology series ; 2

Content: "This book describes the application of polarimetric synthetic aperture radar to Earth remote sensing based on research at the NASA Jet Propulsion Laboratory (JPL). This book synthesizes all current research to provide practical information for both the newcomer and the expert in radar polarimetry. The text offers a concise description of the mathematical fundamentals illustrated with many examples using SAR data, with a main focus on remote sensing of the Earth.The book begins with basics of synthetic aperture radar to provide the basis for understanding how polarimetric SAR images are formed and gives an introduction to the fundamentals of radar polarimetry. It goes on to discuss more advanced polarimetric concepts that allow one to infer more information about the terrain being imaged. In order to analyze data quantitatively, the signals must be calibrated carefully, which the book addresses in a chapter summarizing the basic calibration algorithms. The book concludes with examples of applying polarimetric analysis to scattering from rough surfaces, to infer soil moisture from radar signals"--

Language: English

Keywords: Electronic books.

URL: Click to View

UID:

Format: 1 online resource (xvii, 552 pages) : , illustrations (some color), maps (some color)

Edition: 2nd ed. / Charles Elachi, Jakob van Zyl.

ISBN: 0471475696 , 9780471475699 , 0471783382 , 9780471783381 , 9780471783398 , 0471783390 , 1601190956 , 9781601190956

Series Statement: Wiley series in remote sensing

Content: "The Second Edition of this authoritative book offers readers the essential science and engineering foundation needed to understand remote sensing and apply it in real-world situations. Thoroughly updated to reflect the tremendous technological leaps made since the publication of the first edition, this book covers the gamut of knowledge and skills needed to work in this dynamic field."--Jacket.

Note: Nature and properties of electromagnetic waves -- Solid surfaces sensing in the visible and near infrared -- Solid-surface sensing : thermal infrared -- Solid-surface sensing : microwave -- Solid-surface sensing : microwave and radio frequencies -- Ocean surface sensing -- Basic principles of atmospheric sensing and radiative transfer -- Atmospheric remote sensing in the microwave region -- Millimeter and submillimeter sensing of atmospheres -- Atmospheric remote sensing in the visible and infrared -- Ionospheric sensing.

Additional Edition: Print version: Elachi, Charles. Introduction to the physics and techniques of remote sensing. Hoboken, N.J. : Wiley-Interscience, ©2006 ISBN 0471475696

Language: English

Keywords: Electronic books. ; Electronic books.

DOI: 10.1002/0471783390

URL: https://onlinelibrary.wiley.com/doi/book/10.1002/0471783390

URL: https://onlinelibrary.wiley.com/doi/book/10.1002/0471783390

UID:

Format: 1 online resource (1,014 pages) : , color illustrations, graphs

Edition: 1st ed.

ISBN: 1-63081-050-9

Content: A successor to the classic Artech House Microwave Remote Sensing series, this comprehensive and up-to-date resource previously published by University of Michigan Press provides you with theoretical models, system design and operation, and geoscientific applications of active and passive microwave remote sensing systems. To facilitate understanding and use of the material, the book includes 50 MATLAB-based computer codes and the book's website (http://mrs.eecs.umich.edu/) includes interactive modules based on theoretical and empirical models.

Note: Microwave Radar and Radiometric Remote Sensing; Preface; Chapter 1 Introduction ; Chapter 2 Electromagnetic Wave Propagation and Reflection ; Chapter 3 Remote-Sensing Antennas ; Chapter 4 Microwave Dielectric Properties of Natural Earth Materials; Chapter 5 Radar Scattering ; 5-1 Wave Polarization in a Spherical Coordinate System; 5-2 Scattering Coordinate Systems; 5-2.1 Forward Scattering Alignment (FSA) Convention; 5-2.2 Backscatter Alignment (BSA)Convention; Photo Credits; Computer Codes; 1-1 Why Microwaves for Remote Sensing?; 1-2 A Brief Overview of Microwave Sensors. , 1-3 A Short History of Microwave Remote Sensing1-4 The Electromagnetic Spectrum; 1-5 Basic Operation and Applications of Radar; 1-6 Basic Operation and Applications of Radiometers; 1-7 Image Examples; 2-1 EM Plane Waves; 2-2 Plane-Wave Propagation in Lossless Media; 2-3 Wave Polarization in a Lossless Medium; 2-4 Plane-Wave Propagation in Lossy Media; 2-5 Electromagnetic Power Density; 2-6 Wave Reflection and Transmission at Normal Incidence; 2-7 Wave Reflection and Transmission at Oblique Incidence; 2-8 Reflectivity and Transmissivity; 2-9 Oblique Incidence onto a Lossy Medium. , 2-10 Oblique Incidence onto a Two-Layer CompositePROBLEMS; 3-1 The Hertzian Dipole; 3-2 Antenna Radiation Characteristics; 3-3 Friis Transmission Formula; 3-4 Radiation by Large-Aperture Antennas; 3-5 Rectangular Aperture with Uniform Field Distribution ; 3-6 Circular Aperture with Uniform Field Illumination; 3-7 Nonuniform-Amplitude Illumination; 3-8 Beam Efficiency; 3-9 Antenna Arrays; 3-10 N-Element Array with Uniform Phase Distribution; 3-11 Electronic Scanning of Arrays; 3-12 Antenna Types; 3-13 Active Antennas; PROBLEMS; 4-1 Pure-Water Single-Debye Dielectric Model (f d"50 GHz). , 4-2 Saline-Water Double-Debye Dielectric Model (f d"1000 GHz)4-4 Dielectric Mixing Models for Heterogeneous Materials; 4-5 Sea Ice; 4-6 Dielectric Constant of Snow; 4-7 Dielectric Constant of Dry Rocks; 4-8 Dielectric Constant of Soils; 4-9 Dielectric Constant of Vegetation; PROBLEMS; 1-3.1 Radar; 1-3.2 Radiometers; 1-5.1 Operation of Remote-Sensing Radars; 1-6.1 Radiometer Operation; 1-6.2 Applications of Microwave Radiometry; 2-1.1 Constitutive Parameter; 2-1.2 Maxwell's Equations; 2-1.3 Complex Permittivity; 2-1.4 Wave Equations; 2-3.1 Linear Polarization; 2-3.2 Circular Polarization. , 2-3.3 Elliptical Polarization2-4.1 Low-Loss Dielectric; 2-4.2 Good Conductor; 2-5.1 PlaneWave in a Lossless Medium; 2-5.2 PlaneWave in a Lossy Medium; 2-5.3 Decibel Scale for Power Ratios; 2-6.1 Boundary between Lossless Media; 2-6.2 Boundary between Lossy Media; 2-7.1 Horizontal Polarization-Lossless Media; 2-7.2 Vertical Polarization; 2-10.1 Input Parameters; 2-10.2 Propagation Matrix Method; 2-10.3 Multiple Reflection Method; 3-2.1 Antenna Pattern; 3-2.2 Beam Dimensions; 3-2.3 Antenna Directivity; 3-2.4 Antenna Gain; 3-2.5 Radiation Efficiency; 3-2.6 Effective Area of a Receiving Antenna. , Also available in print.

Additional Edition: ISBN 0-472-11935-4

Language: English

UID:

Format: 1 Online-Ressource (xxviii, 984 Seiten) : , Illustrationen, Diagramme, Karten.

ISBN: 978-1-63081-050-4

Note: A successor to the classic Artech House Microwave Remote Sensing series, this comprehensive and up-to-date resource previously published by University of Michigan Press provides you with theoretical models, system design and operation, and geoscientific applications of active and passive microwave remote sensing systems. To facilitate understanding and use of the material, the book includes 50 MATLAB-based computer codes and the book's website (http://mrs.eecs.umich.edu/) includes interactive modules based on theoretical and empirical models

Additional Edition: Erscheint auch als Druck-Ausgabe ISBN 978-0-472-11935-6

Language: English

Subjects: Geography

Keywords: Radarfernerkundung ; Mikrowellenfernerkundung ; Radiometrie