Introduction to the physics and techniques of remote sensing
著者
書誌事項
Introduction to the physics and techniques of remote sensing
(Wiley series in remote sensing)
Wiley, c2006
2nd ed
- タイトル別名
-
Wiley series in remote sensing and image processing
大学図書館所蔵 全9件
  青森
  岩手
  宮城
  秋田
  山形
  福島
  茨城
  栃木
  群馬
  埼玉
  千葉
  東京
  神奈川
  新潟
  富山
  石川
  福井
  山梨
  長野
  岐阜
  静岡
  愛知
  三重
  滋賀
  京都
  大阪
  兵庫
  奈良
  和歌山
  鳥取
  島根
  岡山
  広島
  山口
  徳島
  香川
  愛媛
  高知
  福岡
  佐賀
  長崎
  熊本
  大分
  宮崎
  鹿児島
  沖縄
  韓国
  中国
  タイ
  イギリス
  ドイツ
  スイス
  フランス
  ベルギー
  オランダ
  スウェーデン
  ノルウェー
  アメリカ
注記
Includes bibliographical references and index
"A Wiley-Interscience publication."
HTTP:URL=http://www.loc.gov/catdir/enhancements/fy0625/2005054053-t.html Information=Table of contents
内容説明・目次
内容説明
The science and engineering of remote sensing--theory and applications 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, including: Physics involved in wave-matter interaction, the building blocks for interpreting data Techniques used to collect data Remote sensing applications The authors have carefully structured and organized the book to introduce readers to the basics, and then move on to more advanced applications. Following an introduction, Chapter 2 sets forth the basic properties of electromagnetic waves and their interactions with matter. Chapters 3 through 7 cover the use of remote sensing in solid surface studies, including oceans. Each chapter covers one major part of the electromagnetic spectrum (e.g., visible/near infrared, thermal infrared, passive microwave, and active microwave).
Chapters 8 through 12 then cover remote sensing in the study of atmospheres and ionospheres. Each chapter first presents the basic interaction mechanism, followed by techniques to acquire, measure, and study the information, or waves, emanating from the medium under investigation. In most cases, a specific advanced sensor is used for illustration. The book is generously illustrated with fifty percent new figures. Numerous illustrations are reproduced in a separate section of color plates. Examples of data acquired from spaceborne sensors are included throughout. Finally, a set of exercises, along with a solutions manual, is provided. This book is based on an upper-level undergraduate and first-year graduate course taught by the authors at the California Institute of Technology. Because of the multidisciplinary nature of the field and its applications, it is appropriate for students in electrical engineering, applied physics, geology, planetary science, astronomy, and aeronautics. It is also recommended for any engineer or scientist interested in working in this exciting field.
目次
Preface. 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. 2. Nature and Properties of Electromagnetic Waves. 2-1 Fundamental Properties of Electromagnetic Waves. 2-2 Nomenclature and Definition of Radiation 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. 3. Solid Surfaces Sensing in the Visible and Near Infrared. 3-1 Source Spectral Characteristics. 3-2 Wave-Surface Interaction Mechanisms. 3-3 Signature of Solid Surface Materials. 3-4 Passive Imaging Sensors. 3-5 Types of Imaging Systems. 3-6 Description of Some Visible/Infrared Imaging Sensors. 3-7 Active Sensors. 3-8 Surface Sensing at Very Short Wavelengths. 3-9 Image Data Analysis. Exercises. References and Further Reading. 4. Solid-Surface Sensing: Thermal Infrared. 4-1 Thermal Radiation Laws. 4-2 Heat Conduction Theory. 4-3 Effect of Periodic Heating. 4-4 Use of Thermal Emission in Surface Remote Sensing. 4-5 Use of Thermal Infrared Spectral Signatures in Sensing. 4-6 Thermal Infrared Sensors. Exercises. References and Further Reading. 5. Solid-Surface Sensing: Microwave Emission. 5-1 Power-Temperature Correspondence. 5-2 Simple Microwave Radiometry Models. 5-3 Applications and Use in Surface Sensing. 5-4 Description of Microwave Radiometers. 5-5 Examples of Developed Radiometers. Exercises. References and Further Reading. 6. Solid-Surface Sensing: Microwave and Radio Frequencies. 6-1 Surface Interaction Mechanism. 6-2 Basic Principles of Radar Sensors. 6-3 Imaging Sensors: Real-Aperture Radars. 6-4 Imaging Sensors: Synthetic-Aperture Radars. 6-5 Nonimaging Radar Sensors: Scatterometers. 6-6 Nonimaging Radar Sensors: Altimeters. 6-7 Nonconventional Radar Sensors. 6-8 Subsurface Sounding. Exercises. References and Further Readings. 7 Ocean Surface Sensing. 7-1 Physical Properties of the Ocean Surface. 7-2 Mapping of the Ocean Topography. 7-3 Surface Wind Mapping. 7-4 Ocean Surface Imaging . Exercises. References and Further Reading. 8. Basic Principles of Atmospheric Sensing and Radiative Transfer. 8-1 Physical Properties of the Atmosphere. 8-2 Atmospheric Composition. 8-3 Particulates and Clouds. 8-4 Wave Interaction Mechanisms in Planetary Atmospheres. 8-5 Optical Thickness. 8-6 Radiative Transfer Equation. 8-7 Case of a Nonscattering Plane Parallel Atmosphere. 8-8 Basic Concepts of Atmospheric Remote Sounding. Exercises. References and Further Reading. 9. Atmospheric Remote Sensing in the Microwave Region. 9-1 Microwave Interactions with Atmospheric Gases. 9-2 Basic Concept of Downlooking Sensors. 9-3 Basic Concept for Uplooking Sensors. 9-4 Basic Concept for Limblooking Sensors. 9-5 Inversion Concepts. 9-6 Basic Elements of Passive Microwave Sensors. 9-7 Surface Pressure Sensing. 9-8 Atmospheric Sounding by Occultation. 9-9 Microwave Scattering by Atmospheric Particles. 9-10 Radar Sounding of Rain. 9-11 Radar Equation for Precipitation Measurement. 9-12 The Tropical Rainfall Measuring Mission (TRMM). Exercises. References and Further Reading. 10. Millimeter and Submillimeter Sensing of Atmospheres. 10-1 Interaction with Atmospheric Constituents. 10-2 Downlooking Sounding. 10-3 Limb Sounding. 10-4 Elements of a Millimeter Sounder. Exercises. References and Further Reading. 11. Atmospheric Remote Sensing in the Visible and Infrared. 11-1 Interaction of Visible and Infrared Radiation with the Atmosphere. 11-2 Downlooking Sounding. 11-3 Limb Sounding. 11-4 Sounding of Atmospheric Motion. 11-5 Atmospheric Sensing at Very Short Wavelengths. Exercises. References and Further Reading. 12. Ionospheric Sensing. 12-1 Properties of Planetary Ionospheres. 12-2 Wave Propagation in Ionized Media. 12-3 Ionospheric Profile Sensing by Topside Sounding. 12-4 Ionospheric Profile by Radio Occultation. Exercises. References and Further Reading. Appendix A. Use of Multiple Sensors For Surface Observations. Appendix B. Summary of Orbital Mechanics Relevant to Remote Sensing. B-1 Circular Orbits. B-1-1 General Characteristics. B-1-2 Geosynchronous Orbits. B-1-3 Sun-Synchronous Orbits. B-1-4 Coverage. B-2 Elliptical Orbits. B-3 Orbit Selection. Exercises. Appendix C. Simplified Weighting Functions. C-1 Case of Downlooking Sensors (Exponential Atmosphere). C-2 Case of Downlooking Sensors (Linear Atmosphere). C-3 Case of Upward Looking Sensors. Appendix D. Compression of a Linear FM Chirp Signal. Index.
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