Microwave scattering and emission models and their applications /

Today, microwave remote sensing has evolved into a valuable and economical tool for a variety of applications. It is used in a wide range of areas, from geological sensing, geographical mapping, and weather monitoring, to GPS positioning, aircraft traffic, and mapping of oil pollution over the sea s...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Autor principal: Fung, Adrian K.
Otros Autores: Chen, K. S. (Kun-Shan), 1959-
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Boston : Artech House, ©2010.
Colección:Artech House remote sensing series.
Temas:
Bistatic radar > Mathematical models.
Radar cross sections.
Radar bistatique > Modèles mathématiques.
Surfaces équivalentes radar.
TECHNOLOGY & ENGINEERING > Radar.
Bistatic radar > Mathematical models
Radar cross sections
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Microwave Scattering and Emission Models for Users; Contents; Preface; Chapter 1 Introduction to Microwave Scattering and Emission Models for Users; 1.1 INTRODUCTION; 1.2 ORGANIZATION; 1.3 MODEL DEFINITIONS FOR ACTIVE AND PASSIVE SENSING; Chapter 2 The Small Perturbation Surface Backscattering Model; 2.1 INTRODUCTION; 2.1.1 Shadowing Considerations; 2.2 ISOTROPIC EXPONENTIAL CORRELATION WITH A GAUSSIANHEIGHT DISTRIBUTION; 2.2.1 Theoretical Trends for the Exponential Correlation; 2.2.2 Comparison with Measurements; 2.3 ISOTROPIC GAUSSIAN CORRELATION WITH A GAUSSIANHEIGHT DISTRIBUTION
  • 2.3.1 Theoretical Trends for the Gaussian Correlation2.3.2 Comparison with Measurements; 2.4 ISOTROPIC X-POWER CORRELATION WITH A GAUSSIAN HEIGHT DISTRIBUTION; 2.4.1 Theoretical Trends for the x-Power Correlation; 2.4.2 Comparison with Measurements; 2.5 ISOTROPIC X-EXPONENTIAL CORRELATION WITH A GAUSSIAN HEIGHT DISTRIBUTION; 2.5.1 Theoretical Trends for the x-Exponential Correlation; 2.5.2 Comparison with Measurements; 2.6 ISOTROPIC EXPONENTIAL-LIKE CORRELATION WITH AGAUSSIAN HEIGHT DISTRIBUTION; 2.6.1 Theoretical Trends for the Exponential-Like Correlation; 2.6.2 Comparison with Measurements
  • 2.7 DISCUSSIONReferences; Chapter 3 The Simplified Integral Equation Surface Backscattering Model; 3.1 INTRODUCTION; 3.1.1 The Simplified IEM Model; 3.1.2 Computer Program Organization; 3.2 ISOTROPIC EXPONENTIAL CORRELATION; 3.2.1 Theoretical Trends in Like Polarized Scattering with Exponential Correlation; 3.2.2 Theoretical Trends in Cross-Polarized Scattering with ExponentialCorrelation; 3.2.3 Comparison with Measurements; 3.3 ISOTROPIC GAUSSIAN CORRELATION; 3.3.1 Theoretical Trends in Like Polarized Scattering with Gaussian Correlation
  • 3.3.2 Theoretical Trends in Cross-Polarized Scattering with Gaussian Correlation3.3.3 Comparison with Measurements and Simulations; 3.4 ISOTROPIC X-POWER CORRELATION; 3.4.1 Theoretical Trends in Like Polarized Scattering with x-PowerCorrelation; 3.4.2 Theoretical Trends in Cross-Polarized Scattering with x-Power Correlation; 3.4.3 Comparison with Measurements and Simulations; 3.5 ISOTROPIC X-EXPONENTIAL CORRELATION; 3.5.1 Theoretical Trends in Like Polarized Scattering with x-ExponentialCorrelation; 3.5.2 Comparison with Measurements; 3.6 ISOTROPIC EXPONENTIAL-LIKE CORRELATION
  • 3.6.1 A Comparison of Spectral Contents3.6.2 Theoretical Trends in Like Polarized Scattering with Exponential-LikeCorrelation; 3.6.3 Comparison with Measurements and Simulations; 3.7 DISCUSSION; References; Chapter 4 The IEM-B Surface Backscattering Model; 4.1 INTRODUCTION; 4.2 ISOTROPIC EXPONENTIAL CORRELATION; 4.2.1 Theoretical Trends for Like Polarization with Exponential Correlation; 4.2.2 Comparison with Measurements; 4.3 ISOTROPIC GAUSSIAN CORRELATION; 4.3.1 Theoretical Trends for Like Polarization with Gaussian Correlation; 4.3.2 Comparison with Measurements and Simulations

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