Scattering by Obstacles
β Alexander G. Ramm
π Library
π
1986
π D. Reidel; Sold and distributed in the U.S.A. by K
π English
β¦ LIBER β¦
π
Scattering of Electromagnetic Waves by Obstacles
β Scribed by Gerhard Kristensson
- Publisher
- SciTech
- Year
- 2016
- Tongue
- English
- Leaves
- 764
- Series
- Mario Boella Series on Electromagnetism in Information and Communication
- Category
- Library
β¬ Acquire This Volume
No coin nor oath required. For personal study only.
β¦ Synopsis
Electromagnetic (EM) wave scattering is of fundamental importance to antenna and radar design engineering, and the increasing interest in metamaterials has created a need for new approaches to solving scattering problems for characterizing engineered media. This book lays the theoretical foundation for new computer programs in computational electromagnetics (CEM) and meets the need of todayβs researchers. This book represents over 30 years of the authorβs experience teaching this topic, with extensive lectures notes expanded to include advanced concepts and mathematical solutions to cover modern effects on metamaterials and related advanced complexities.
Problems and solutions at the end of each chapter help to reinforce concepts and highlight applications. This is an ideal text for advanced graduate students and researchers in EM and applied physics
β¦ Table of Contents
Content: Preface
Foreword
Acknowledgment
1. Basic Equations
1.1. The Maxwell Equations
1.2. Constitutive Relations
1.3. Time-Harmonic Fields and Fourier Transform
1.4. Coherence and Degree of Polarization
Problems for Chapter 1
2. The Green Functions and Dyadics
2.1. The Green Functions in Isotropic Media
2.2. The Green Dyadics in Isotropic Media
2.3. The Green Dyadic in Anisotropic Media
2.4. The Green Dyadic in Biisotropic Media
2.5. Cerenkov Radiation
2.6. Time-Domain Problem
Problems for Chapter 2
3. Integral Representation of Fields
3.1. Two Scalar Fields. 3.2. Vector and Scalar Fields3.3. Integral Representations of the Maxwell Equations
3.4. Dyadic and Vector Fields
3.5. Limit Values of the Scalar Integral Representations
3.6. Limit Values of the Vector Integral Representations-Vector Version
3.7. Limit Values of the Vector Integral Representations-Dyadic Version
3.8. Integral Representation for Biisotropic Materials
3.9. Integral Representations in the Time Domain
Problems for Chapter 3
4. Introductory Scattering Theory
4.1. The Far Zone
4.2. Cross Sections
4.3. Scattering Dyadic (Matrix)
4.4. Optical Theorem. 4.5. Plane Interface Case and Babinet's PrincipleProblems for Chapter 4
5. Scattering in the Time Domain
5.1. The Scattering Problem
5.2. Energy Balance in the Time Domain
5.3. Connection to the Time-Harmonic Results
5.4. Optical Theorem
5.5. Some Applications of the Optical Theorem
Problems for Chapter 5
6. Approximations and Applications
6.1. Long Wavelength Approximation
6.2. Weak-Scatterer Approximation
6.3. High-Frequency Approximation
6.4. Sum Rule for the Extinction Cross Section
6.5. Scattering by Many Scatterers-Multiple Scattering
Problems for Chapter 6. 7. Spherical Vector Waves7.1. Preparatory Discussions
7.2. Definition of Spherical Vector Waves
7.3. Orthogonality and Reciprocity Relations
7.4. Some Properties of the Spherical Vector Waves
7.5. Expansion of the Green Dyadic
7.6. Null-Field Equations
7.7. Expansion of Sources
7.8. Far Field Amplitude and the Transition Matrix
7.9. Dipole Moments of a Scatterer
Problems for Chapter 7
8. Scattering by Spherical Objects
8.1. Scattering by a Perfectly Conducting Sphere
8.2. Scattering by a Dielectric Sphere
8.3. Scattering by Layered Spherical Objects. 8.4. Scattering by an Anisotropic Sphere8.5. Scattering by a Biisotropic Sphere
Problems for Chapter 8
9. The Null-Field Approach
9.1. The T-Matrix for a Single Homogeneous Scatterer
9.2. The T-Matrix for a Collection of Scatterers
9.3. Obstacle above a Ground Plane
Problems for Chapter 9
10. Propagation in Stratified Media
10.1. Basic Equations
10.2. The Fundamental Equation
10.3. Wave Splitting
10.4. Propagation of Fields-the Propagator Dyadic
10.5. Propagator Dyadics-Homogeneous Layers
10.6. Examples
10.7. Numerical Computations
10.8. Asymptotic Analysis. 10.9. The Green Dyadic.
β¦ Subjects
Electromagnetic waves;Scattering;Mathematical models;Quantum Theory
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