Electromagnetic Radiation, Scattering, and Diffraction:
Gespeichert in:
| 1. Verfasser: | |
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| Format: | Elektronisch E-Book |
| Sprache: | English |
| Veröffentlicht: |
Hoboken, NJ
John Wiley & Sons, Incorporated
2022
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| Schriftenreihe: | IEEE Press Series on Electromagnetic Wave Theory Ser
|
| Online-Zugang: | DE-573 |
| Beschreibung: | Description based on publisher supplied metadata and other sources |
| Beschreibung: | 1 Online-Ressource (xxiii, 1117 Seiten) |
| ISBN: | 9781119810520 9781119810537 9781119810544 |
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| 100 | 1 | |a Pathak, Prabhakar H. |d 1942- |e Verfasser |0 (DE-588)1266908013 |4 aut | |
| 245 | 1 | 0 | |a Electromagnetic Radiation, Scattering, and Diffraction |c Prabhakar H. Pathak and Robert J. Burkholder |
| 264 | 1 | |a Hoboken, NJ |b John Wiley & Sons, Incorporated |c 2022 | |
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| 490 | 0 | |a IEEE Press Series on Electromagnetic Wave Theory Ser | |
| 500 | |a Description based on publisher supplied metadata and other sources | ||
| 505 | 8 | |a Cover -- Title Page -- Copyright -- Contents -- About the Authors -- Preface -- Acknowledgments -- 1 Maxwell's Equations, Constitutive Relations, Wave Equation, and Polarization -- 1.1 Introductory Comments -- 1.2 Maxwell's Equations -- 1.3 Constitutive Relations -- 1.4 Frequency Domain Fields -- 1.5 Kramers-Kronig Relationship -- 1.6 Vector and Scalar Wave Equations -- 1.6.1 Vector Wave Equations for EM Fields -- 1.6.2 Scalar Wave Equations for EM Fields -- 1.7 Separable Solutions of the Source-Free Wave Equation in Rectangular Coordinates and for Isotropic Homogeneous Media. Plane Waves -- 1.8 Polarization of Plane Waves, Poincare Sphere, and Stokes Parameters -- 1.8.1 Polarization States -- 1.8.2 General Elliptical Polarization -- 1.8.3 Decomposition of a Polarization State into Circularly Polarized Components -- 1.8.4 Poincare Sphere for Describing Polarization States -- 1.9 Phase and Group Velocity -- 1.10 Separable Solutions of the Source-Free Wave Equation in Cylindrical and Spherical Coordinates and for Isotropic Homogeneous Media -- 1.10.1 Source-Free Cylindrical Wave Solutions -- 1.10.2 Source-Free Spherical Wave Solutions -- References -- 2 EM Boundary and Radiation Conditions -- 2.1 EM Field Behavior Across a Boundary Surface -- 2.2 Radiation Boundary Condition -- 2.3 Boundary Conditions at a Moving Interface -- 2.3.1 Nonrelativistic Moving Boundary Conditions -- 2.3.2 Derivation of the Nonrelativistic Field Transformations -- 2.3.3 EM Field Transformations Based on the Special Theory of Relativity -- 2.4 Constitutive Relations for a Moving Medium -- References -- 3 Plane Wave Propagation in Planar Layered Media -- 3.1 Introduction -- 3.2 Plane Wave Reection from a Planar Boundary Between Two Di erent Media -- 3.2.1 Perpendicular Polarization Case -- 3.2.2 Parallel Polarization Case -- 3.2.3 Brewster Angle θb | |
| 505 | 8 | |a 3.2.4 Critical Angle θc -- 3.2.5 Plane Wave Incident on a Lossy Half Space -- 3.2.6 Doppler Shift for Wave Reection from a Moving Mirror -- 3.3 Reection and Transmission of a Plane Wave Incident on a Planar Stratified Isotropic Medium Using a Transmission Matrix Approach -- 3.4 Plane Waves in Anisotropic Homogeneous Media -- 3.5 State Space Formulation for Waves in Planar Anisotropic Layered Media -- 3.5.1 Development of State Space Based Field Equations -- 3.5.2 Reection and Transmission of Plane Waves at the Interface Between Two Anisotropic Half Spaces -- 3.5.3 Transmission Type Matrix Analysis of Plane Waves in Multilayered Anisotropic Media -- References -- 4 Plane Wave Spectral Representation for EM Fields -- 4.1 Introduction -- 4.2 PWS Development -- References -- 5 Electromagnetic Potentials and Fields of Sources in Unbounded Regions -- 5.1 Introduction to Vector and Scalar Potentials -- 5.2 Construction of the Solution for Ā -- 5.3 Calculation of Fields from Potentials -- 5.4 Time Dependent Potentials for Sources and Fields in Unbounded Regions -- 5.5 Potentials and Fields of a Moving Point Charge -- 5.6 Cerenkov Radiation -- 5.7 Direct Calculation of Fields of Sources in Unbounded Regions Using a Dyadic Green's Function -- 5.7.1 Fields of Sources in Unbounded, Isotropic, Homogeneous Media in Terms of a Closed Form Representation of Green's Dyadic, G0 -- 5.7.2 On the Singular Nature of G0(rr) for Observation Points Within the Source Region -- 5.7.3 Representation of the Green's Dyadic G0 in Terms of an Integral in the Wavenumber (k) Space -- 5.7.4 Electromagnetic Radiation by a Source in a General Bianisotropic Medium Using a Green's Dyadic Ga in k-Space -- References -- 6 Electromagnetic Field Theorems and Related Topics -- 6.1 Conservation of Charge -- 6.2 Conservation of Power -- 6.3 Conservation of Momentum -- 6.4 Radiation Pressure | |
| 505 | 8 | |a 6.5 Duality Theorem -- 6.6 Reciprocity Theorems and Conservation of Reactions -- 6.6.1 The Lorentz Reciprocity Theorem -- 6.6.2 Reciprocity Theorem for Bianisotropic Media -- 6.7 Uniqueness Theorem -- 6.8 Image Theorems -- 6.9 Equivalence Theorems -- 6.9.1 Volume Equivalence Theorem for EM Scattering -- 6.9.2 A Surface Equivalence Theorem for EM Scattering -- 6.9.3 A Surface Equivalence Theorem for Antennas -- 6.10 Antenna Impedance -- 6.11 Antenna Equivalent Circuit -- 6.12 The Receiving Antenna Problem -- 6.13 Expressions for Antenna Mutual Coupling Based on Generalized Reciprocity Theorems -- 6.13.1 Circuit Form of the Reciprocity Theorem for Antenna Mutual Coupling -- 6.13.2 A Mixed Circuit Field Form of a Generalized Reciprocity Theorem for Antenna Mutual Coupling -- 6.13.3 A Mutual Admittance Expression for Slot Antennas -- 6.13.4 Antenna Mutual Coupling, Reaction Concept, and Antenna Measurements -- 6.14 Relation Between Antenna and Scattering Problems -- 6.14.1 Exterior Radiation by a Slot Aperture Antenna Configuration -- 6.14.2 Exterior Radiation by a Monopole Antenna Configuration -- 6.15 Radar Cross Section -- 6.16 Antenna Directive Gain -- 6.17 Field Decomposition Theorem -- References -- 7 Modal Techniques for the Analysis of Guided Waves, Resonant Cavities, and Periodic Structures -- 7.1 On Modal Analysis of Some Guided Wave Problems -- 7.2 Classification of Modal Fields in Uniform Guiding Structures -- 7.2.1 TEMz Guided waves -- 7.3 TMz Guided Waves -- 7.4 TEz Guided Waves -- 7.5 Modal Expansions in Closed Uniform Waveguides -- 7.5.1 TMz Modes -- 7.5.2 TEz Modes -- 7.5.3 Orthogonality of Modes in Closed Perfectly Conducting Uniform Waveguides -- 7.6 E ect of Losses in Closed Guided Wave Structures -- 7.7 Source Excited Uniform Closed Perfectly Conducting Waveguides -- 7.8 An Analysis of Some Closed Metallic Waveguides | |
| 505 | 8 | |a 7.8.1 Modes in a Parallel Plate Waveguide -- 7.8.2 Modes in a Rectangular Waveguide -- 7.8.3 Modes in a Circular Waveguide -- 7.8.4 Coaxial Waveguide -- 7.8.5 Obstacles and Discontinuities in Waveguides -- 7.8.6 Modal Propagation Past a Slot in a Waveguide -- 7.9 Closed and Open Waveguides Containing Penetrable Materials and Coatings -- 7.9.1 Material-Loaded Closed PEC Waveguide -- 7.9.2 Material Slab Waveguide -- 7.9.3 Grounded Material Slab Waveguide -- 7.9.4 The Goubau Line -- 7.9.5 Circular Cylindrical Optical Fiber Waveguides -- 7.10 Modal Analysis of Resonators -- 7.10.1 Rectangular Waveguide Cavity Resonator -- 7.10.2 Circular Waveguide Cavity Resonator -- 7.10.3 Dielectric Resonators -- 7.11 Excitation of Resonant Cavities -- 7.12 Modal Analysis of Periodic Arrays -- 7.12.1 Floquet Modal Analysis of an Infinite Planar Periodic Array of Electric Current Sources -- 7.12.2 Floquet Modal Analysis of an Infinite Planar Periodic Array of Current Sources Configured in a Skewed Grid -- 7.13 Higher-Order Floquet Modes and Associated Grating Lobe Circle Diagrams for Infinite Planar Periodic Arrays -- 7.13.1 Grating Lobe Circle Diagrams -- 7.14 On Waves Guided and Radiated by Periodic Structures -- 7.15 Scattering by a Planar Periodic Array -- 7.15.1 Analysis of the EM Plane Wave Scattering by an Infinite Periodic Slot Array in a Planar PEC Screen -- 7.16 Finite 1-D and 2-D Periodic Array of Sources -- 7.16.1 Analysis of Finite 1-D Periodic Arrays for the Case of Uniform Source Distribution and Far Zone Observation -- 7.16.2 Analysis of Finite 2-D Periodic Arrays for the Case of Uniform Distribution and Far Zone Observation -- 7.16.3 Floquet Modal Representation for Near and Far Fields of 1-D Nonuniform Finite Periodic Array Distributions | |
| 505 | 8 | |a 7.16.4 Floquet Modal Representation for Near and Far Fields of 2-D Nonuniform Planar Periodic Finite Array Distributions -- References -- 8 Green's Functions for the Analysis of One-Dimensional Source-Excited Wave Problems -- 8.1 Introduction to the Sturm-Liouville Form of Di erential Equation for 1-D Wave Problems -- 8.2 Formulation of the Solution to the Sturm-Liouville Problem via the 1-D Green's Function Approach -- 8.3 Conditions Under Which the Green's Function Is Symmetric -- 8.4 Construction of the Green's Function G(x|x') -- 8.4.1 General Procedure to Obtain G(x|x') -- 8.5 Alternative Simplified Construction of G(x|x') Valid for the SymmetricCase -- 8.6 On the Existence and Uniqueness of G(x|x') -- 8.7 Eigenfunction Expansion Representation for G(x|x') -- 8.8 Delta Function Completeness Relation and the Construction of Eigenfunctions from G(x|x') = U(x< -- )T(x)/W -- 8.9 Explicit Representation of G(x|x') Using Step Functions -- References -- 9 Applications of One-Dimensional Green's Function Approach for the Analysis of Single and Coupled Set of EM Source Excited Transmission Lines -- 9.1 Introduction -- 9.2 Analytical Formulation for a Single Transmission Line Made Up of Two Conductors -- 9.3 Wave Solution for the Two Conductor Lines When There Are No Impressed Sources Distributed Anywhere Within the Line -- 9.4 Wave Solution for the Case of Impressed Sources Placed Anywhere on a Two Conductor Line -- 9.5 Excitation of a Two Conductor Transmission Line by an Externally Incident lectromagnetic Wave -- 9.6 A Matrix Green's Function Approach for Analyzing a Set of Coupled Transmission Lines -- 9.7 Solution to the Special Case of Two Coupled Lines (N = 2) with Homogeneous Dirichlet or Neumann End Conditions -- 9.8 Development of the Multiport Impedance Matrix for a Set of Coupled Transmission Lines | |
| 505 | 8 | |a 9.9 Coupled Transmission Line Problems with Voltage Sources and Load Impedances at the End Terminals | |
| 700 | 1 | |a Burkholder, Robert J. |e Sonstige |0 (DE-588)1266908706 |4 oth | |
| 776 | 0 | 8 | |i Erscheint auch als |n Druck-Ausgabe |a Pathak, Prabhakar H. |t Electromagnetic Radiation, Scattering, and Diffraction |d Newark : John Wiley & Sons, Incorporated,c2021 |z 978-1-119-81051-3 |
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Datensatz im Suchindex
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| author | Pathak, Prabhakar H. 1942- |
| author_GND | (DE-588)1266908013 (DE-588)1266908706 |
| author_facet | Pathak, Prabhakar H. 1942- |
| author_role | aut |
| author_sort | Pathak, Prabhakar H. 1942- |
| author_variant | p h p ph php |
| building | Verbundindex |
| bvnumber | BV048221332 |
| collection | ZDB-30-PQE ZDB-35-WEL |
| contents | Cover -- Title Page -- Copyright -- Contents -- About the Authors -- Preface -- Acknowledgments -- 1 Maxwell's Equations, Constitutive Relations, Wave Equation, and Polarization -- 1.1 Introductory Comments -- 1.2 Maxwell's Equations -- 1.3 Constitutive Relations -- 1.4 Frequency Domain Fields -- 1.5 Kramers-Kronig Relationship -- 1.6 Vector and Scalar Wave Equations -- 1.6.1 Vector Wave Equations for EM Fields -- 1.6.2 Scalar Wave Equations for EM Fields -- 1.7 Separable Solutions of the Source-Free Wave Equation in Rectangular Coordinates and for Isotropic Homogeneous Media. Plane Waves -- 1.8 Polarization of Plane Waves, Poincare Sphere, and Stokes Parameters -- 1.8.1 Polarization States -- 1.8.2 General Elliptical Polarization -- 1.8.3 Decomposition of a Polarization State into Circularly Polarized Components -- 1.8.4 Poincare Sphere for Describing Polarization States -- 1.9 Phase and Group Velocity -- 1.10 Separable Solutions of the Source-Free Wave Equation in Cylindrical and Spherical Coordinates and for Isotropic Homogeneous Media -- 1.10.1 Source-Free Cylindrical Wave Solutions -- 1.10.2 Source-Free Spherical Wave Solutions -- References -- 2 EM Boundary and Radiation Conditions -- 2.1 EM Field Behavior Across a Boundary Surface -- 2.2 Radiation Boundary Condition -- 2.3 Boundary Conditions at a Moving Interface -- 2.3.1 Nonrelativistic Moving Boundary Conditions -- 2.3.2 Derivation of the Nonrelativistic Field Transformations -- 2.3.3 EM Field Transformations Based on the Special Theory of Relativity -- 2.4 Constitutive Relations for a Moving Medium -- References -- 3 Plane Wave Propagation in Planar Layered Media -- 3.1 Introduction -- 3.2 Plane Wave Reection from a Planar Boundary Between Two Di erent Media -- 3.2.1 Perpendicular Polarization Case -- 3.2.2 Parallel Polarization Case -- 3.2.3 Brewster Angle θb 3.2.4 Critical Angle θc -- 3.2.5 Plane Wave Incident on a Lossy Half Space -- 3.2.6 Doppler Shift for Wave Reection from a Moving Mirror -- 3.3 Reection and Transmission of a Plane Wave Incident on a Planar Stratified Isotropic Medium Using a Transmission Matrix Approach -- 3.4 Plane Waves in Anisotropic Homogeneous Media -- 3.5 State Space Formulation for Waves in Planar Anisotropic Layered Media -- 3.5.1 Development of State Space Based Field Equations -- 3.5.2 Reection and Transmission of Plane Waves at the Interface Between Two Anisotropic Half Spaces -- 3.5.3 Transmission Type Matrix Analysis of Plane Waves in Multilayered Anisotropic Media -- References -- 4 Plane Wave Spectral Representation for EM Fields -- 4.1 Introduction -- 4.2 PWS Development -- References -- 5 Electromagnetic Potentials and Fields of Sources in Unbounded Regions -- 5.1 Introduction to Vector and Scalar Potentials -- 5.2 Construction of the Solution for Ā -- 5.3 Calculation of Fields from Potentials -- 5.4 Time Dependent Potentials for Sources and Fields in Unbounded Regions -- 5.5 Potentials and Fields of a Moving Point Charge -- 5.6 Cerenkov Radiation -- 5.7 Direct Calculation of Fields of Sources in Unbounded Regions Using a Dyadic Green's Function -- 5.7.1 Fields of Sources in Unbounded, Isotropic, Homogeneous Media in Terms of a Closed Form Representation of Green's Dyadic, G0 -- 5.7.2 On the Singular Nature of G0(rr) for Observation Points Within the Source Region -- 5.7.3 Representation of the Green's Dyadic G0 in Terms of an Integral in the Wavenumber (k) Space -- 5.7.4 Electromagnetic Radiation by a Source in a General Bianisotropic Medium Using a Green's Dyadic Ga in k-Space -- References -- 6 Electromagnetic Field Theorems and Related Topics -- 6.1 Conservation of Charge -- 6.2 Conservation of Power -- 6.3 Conservation of Momentum -- 6.4 Radiation Pressure 6.5 Duality Theorem -- 6.6 Reciprocity Theorems and Conservation of Reactions -- 6.6.1 The Lorentz Reciprocity Theorem -- 6.6.2 Reciprocity Theorem for Bianisotropic Media -- 6.7 Uniqueness Theorem -- 6.8 Image Theorems -- 6.9 Equivalence Theorems -- 6.9.1 Volume Equivalence Theorem for EM Scattering -- 6.9.2 A Surface Equivalence Theorem for EM Scattering -- 6.9.3 A Surface Equivalence Theorem for Antennas -- 6.10 Antenna Impedance -- 6.11 Antenna Equivalent Circuit -- 6.12 The Receiving Antenna Problem -- 6.13 Expressions for Antenna Mutual Coupling Based on Generalized Reciprocity Theorems -- 6.13.1 Circuit Form of the Reciprocity Theorem for Antenna Mutual Coupling -- 6.13.2 A Mixed Circuit Field Form of a Generalized Reciprocity Theorem for Antenna Mutual Coupling -- 6.13.3 A Mutual Admittance Expression for Slot Antennas -- 6.13.4 Antenna Mutual Coupling, Reaction Concept, and Antenna Measurements -- 6.14 Relation Between Antenna and Scattering Problems -- 6.14.1 Exterior Radiation by a Slot Aperture Antenna Configuration -- 6.14.2 Exterior Radiation by a Monopole Antenna Configuration -- 6.15 Radar Cross Section -- 6.16 Antenna Directive Gain -- 6.17 Field Decomposition Theorem -- References -- 7 Modal Techniques for the Analysis of Guided Waves, Resonant Cavities, and Periodic Structures -- 7.1 On Modal Analysis of Some Guided Wave Problems -- 7.2 Classification of Modal Fields in Uniform Guiding Structures -- 7.2.1 TEMz Guided waves -- 7.3 TMz Guided Waves -- 7.4 TEz Guided Waves -- 7.5 Modal Expansions in Closed Uniform Waveguides -- 7.5.1 TMz Modes -- 7.5.2 TEz Modes -- 7.5.3 Orthogonality of Modes in Closed Perfectly Conducting Uniform Waveguides -- 7.6 E ect of Losses in Closed Guided Wave Structures -- 7.7 Source Excited Uniform Closed Perfectly Conducting Waveguides -- 7.8 An Analysis of Some Closed Metallic Waveguides 7.8.1 Modes in a Parallel Plate Waveguide -- 7.8.2 Modes in a Rectangular Waveguide -- 7.8.3 Modes in a Circular Waveguide -- 7.8.4 Coaxial Waveguide -- 7.8.5 Obstacles and Discontinuities in Waveguides -- 7.8.6 Modal Propagation Past a Slot in a Waveguide -- 7.9 Closed and Open Waveguides Containing Penetrable Materials and Coatings -- 7.9.1 Material-Loaded Closed PEC Waveguide -- 7.9.2 Material Slab Waveguide -- 7.9.3 Grounded Material Slab Waveguide -- 7.9.4 The Goubau Line -- 7.9.5 Circular Cylindrical Optical Fiber Waveguides -- 7.10 Modal Analysis of Resonators -- 7.10.1 Rectangular Waveguide Cavity Resonator -- 7.10.2 Circular Waveguide Cavity Resonator -- 7.10.3 Dielectric Resonators -- 7.11 Excitation of Resonant Cavities -- 7.12 Modal Analysis of Periodic Arrays -- 7.12.1 Floquet Modal Analysis of an Infinite Planar Periodic Array of Electric Current Sources -- 7.12.2 Floquet Modal Analysis of an Infinite Planar Periodic Array of Current Sources Configured in a Skewed Grid -- 7.13 Higher-Order Floquet Modes and Associated Grating Lobe Circle Diagrams for Infinite Planar Periodic Arrays -- 7.13.1 Grating Lobe Circle Diagrams -- 7.14 On Waves Guided and Radiated by Periodic Structures -- 7.15 Scattering by a Planar Periodic Array -- 7.15.1 Analysis of the EM Plane Wave Scattering by an Infinite Periodic Slot Array in a Planar PEC Screen -- 7.16 Finite 1-D and 2-D Periodic Array of Sources -- 7.16.1 Analysis of Finite 1-D Periodic Arrays for the Case of Uniform Source Distribution and Far Zone Observation -- 7.16.2 Analysis of Finite 2-D Periodic Arrays for the Case of Uniform Distribution and Far Zone Observation -- 7.16.3 Floquet Modal Representation for Near and Far Fields of 1-D Nonuniform Finite Periodic Array Distributions 7.16.4 Floquet Modal Representation for Near and Far Fields of 2-D Nonuniform Planar Periodic Finite Array Distributions -- References -- 8 Green's Functions for the Analysis of One-Dimensional Source-Excited Wave Problems -- 8.1 Introduction to the Sturm-Liouville Form of Di erential Equation for 1-D Wave Problems -- 8.2 Formulation of the Solution to the Sturm-Liouville Problem via the 1-D Green's Function Approach -- 8.3 Conditions Under Which the Green's Function Is Symmetric -- 8.4 Construction of the Green's Function G(x|x') -- 8.4.1 General Procedure to Obtain G(x|x') -- 8.5 Alternative Simplified Construction of G(x|x') Valid for the SymmetricCase -- 8.6 On the Existence and Uniqueness of G(x|x') -- 8.7 Eigenfunction Expansion Representation for G(x|x') -- 8.8 Delta Function Completeness Relation and the Construction of Eigenfunctions from G(x|x') = U(x< -- )T(x)/W -- 8.9 Explicit Representation of G(x|x') Using Step Functions -- References -- 9 Applications of One-Dimensional Green's Function Approach for the Analysis of Single and Coupled Set of EM Source Excited Transmission Lines -- 9.1 Introduction -- 9.2 Analytical Formulation for a Single Transmission Line Made Up of Two Conductors -- 9.3 Wave Solution for the Two Conductor Lines When There Are No Impressed Sources Distributed Anywhere Within the Line -- 9.4 Wave Solution for the Case of Impressed Sources Placed Anywhere on a Two Conductor Line -- 9.5 Excitation of a Two Conductor Transmission Line by an Externally Incident lectromagnetic Wave -- 9.6 A Matrix Green's Function Approach for Analyzing a Set of Coupled Transmission Lines -- 9.7 Solution to the Special Case of Two Coupled Lines (N = 2) with Homogeneous Dirichlet or Neumann End Conditions -- 9.8 Development of the Multiport Impedance Matrix for a Set of Coupled Transmission Lines 9.9 Coupled Transmission Line Problems with Voltage Sources and Load Impedances at the End Terminals |
| ctrlnum | (ZDB-30-PQE)EBC6817987 (ZDB-30-PAD)EBC6817987 (ZDB-89-EBL)EBL6817987 (OCoLC)1287132154 (DE-599)BVBBV048221332 |
| dewey-full | 539.2 |
| dewey-hundreds | 500 - Natural sciences and mathematics |
| dewey-ones | 539 - Modern physics |
| dewey-raw | 539.2 |
| dewey-search | 539.2 |
| dewey-sort | 3539.2 |
| dewey-tens | 530 - Physics |
| discipline | Physik |
| discipline_str_mv | Physik |
| format | Electronic eBook |
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Burkholder</subfield></datafield><datafield tag="264" ind1=" " ind2="1"><subfield code="a">Hoboken, NJ</subfield><subfield code="b">John Wiley & Sons, Incorporated</subfield><subfield code="c">2022</subfield></datafield><datafield tag="264" ind1=" " ind2="4"><subfield code="c">©2022</subfield></datafield><datafield tag="300" ind1=" " ind2=" "><subfield code="a">1 Online-Ressource (xxiii, 1117 Seiten)</subfield></datafield><datafield tag="336" ind1=" " ind2=" "><subfield code="b">txt</subfield><subfield code="2">rdacontent</subfield></datafield><datafield tag="337" ind1=" " ind2=" "><subfield code="b">c</subfield><subfield code="2">rdamedia</subfield></datafield><datafield tag="338" ind1=" " ind2=" "><subfield code="b">cr</subfield><subfield code="2">rdacarrier</subfield></datafield><datafield tag="490" ind1="0" ind2=" "><subfield code="a">IEEE Press Series on Electromagnetic Wave Theory Ser</subfield></datafield><datafield tag="500" ind1=" " ind2=" "><subfield code="a">Description based on publisher supplied metadata and other sources</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">Cover -- Title Page -- Copyright -- Contents -- About the Authors -- Preface -- Acknowledgments -- 1 Maxwell's Equations, Constitutive Relations, Wave Equation, and Polarization -- 1.1 Introductory Comments -- 1.2 Maxwell's Equations -- 1.3 Constitutive Relations -- 1.4 Frequency Domain Fields -- 1.5 Kramers-Kronig Relationship -- 1.6 Vector and Scalar Wave Equations -- 1.6.1 Vector Wave Equations for EM Fields -- 1.6.2 Scalar Wave Equations for EM Fields -- 1.7 Separable Solutions of the Source-Free Wave Equation in Rectangular Coordinates and for Isotropic Homogeneous Media. Plane Waves -- 1.8 Polarization of Plane Waves, Poincare Sphere, and Stokes Parameters -- 1.8.1 Polarization States -- 1.8.2 General Elliptical Polarization -- 1.8.3 Decomposition of a Polarization State into Circularly Polarized Components -- 1.8.4 Poincare Sphere for Describing Polarization States -- 1.9 Phase and Group Velocity -- 1.10 Separable Solutions of the Source-Free Wave Equation in Cylindrical and Spherical Coordinates and for Isotropic Homogeneous Media -- 1.10.1 Source-Free Cylindrical Wave Solutions -- 1.10.2 Source-Free Spherical Wave Solutions -- References -- 2 EM Boundary and Radiation Conditions -- 2.1 EM Field Behavior Across a Boundary Surface -- 2.2 Radiation Boundary Condition -- 2.3 Boundary Conditions at a Moving Interface -- 2.3.1 Nonrelativistic Moving Boundary Conditions -- 2.3.2 Derivation of the Nonrelativistic Field Transformations -- 2.3.3 EM Field Transformations Based on the Special Theory of Relativity -- 2.4 Constitutive Relations for a Moving Medium -- References -- 3 Plane Wave Propagation in Planar Layered Media -- 3.1 Introduction -- 3.2 Plane Wave Reection from a Planar Boundary Between Two Di erent Media -- 3.2.1 Perpendicular Polarization Case -- 3.2.2 Parallel Polarization Case -- 3.2.3 Brewster Angle θb</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">3.2.4 Critical Angle θc -- 3.2.5 Plane Wave Incident on a Lossy Half Space -- 3.2.6 Doppler Shift for Wave Reection from a Moving Mirror -- 3.3 Reection and Transmission of a Plane Wave Incident on a Planar Stratified Isotropic Medium Using a Transmission Matrix Approach -- 3.4 Plane Waves in Anisotropic Homogeneous Media -- 3.5 State Space Formulation for Waves in Planar Anisotropic Layered Media -- 3.5.1 Development of State Space Based Field Equations -- 3.5.2 Reection and Transmission of Plane Waves at the Interface Between Two Anisotropic Half Spaces -- 3.5.3 Transmission Type Matrix Analysis of Plane Waves in Multilayered Anisotropic Media -- References -- 4 Plane Wave Spectral Representation for EM Fields -- 4.1 Introduction -- 4.2 PWS Development -- References -- 5 Electromagnetic Potentials and Fields of Sources in Unbounded Regions -- 5.1 Introduction to Vector and Scalar Potentials -- 5.2 Construction of the Solution for Ā -- 5.3 Calculation of Fields from Potentials -- 5.4 Time Dependent Potentials for Sources and Fields in Unbounded Regions -- 5.5 Potentials and Fields of a Moving Point Charge -- 5.6 Cerenkov Radiation -- 5.7 Direct Calculation of Fields of Sources in Unbounded Regions Using a Dyadic Green's Function -- 5.7.1 Fields of Sources in Unbounded, Isotropic, Homogeneous Media in Terms of a Closed Form Representation of Green's Dyadic, G0 -- 5.7.2 On the Singular Nature of G0(rr) for Observation Points Within the Source Region -- 5.7.3 Representation of the Green's Dyadic G0 in Terms of an Integral in the Wavenumber (k) Space -- 5.7.4 Electromagnetic Radiation by a Source in a General Bianisotropic Medium Using a Green's Dyadic Ga in k-Space -- References -- 6 Electromagnetic Field Theorems and Related Topics -- 6.1 Conservation of Charge -- 6.2 Conservation of Power -- 6.3 Conservation of Momentum -- 6.4 Radiation Pressure</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">6.5 Duality Theorem -- 6.6 Reciprocity Theorems and Conservation of Reactions -- 6.6.1 The Lorentz Reciprocity Theorem -- 6.6.2 Reciprocity Theorem for Bianisotropic Media -- 6.7 Uniqueness Theorem -- 6.8 Image Theorems -- 6.9 Equivalence Theorems -- 6.9.1 Volume Equivalence Theorem for EM Scattering -- 6.9.2 A Surface Equivalence Theorem for EM Scattering -- 6.9.3 A Surface Equivalence Theorem for Antennas -- 6.10 Antenna Impedance -- 6.11 Antenna Equivalent Circuit -- 6.12 The Receiving Antenna Problem -- 6.13 Expressions for Antenna Mutual Coupling Based on Generalized Reciprocity Theorems -- 6.13.1 Circuit Form of the Reciprocity Theorem for Antenna Mutual Coupling -- 6.13.2 A Mixed Circuit Field Form of a Generalized Reciprocity Theorem for Antenna Mutual Coupling -- 6.13.3 A Mutual Admittance Expression for Slot Antennas -- 6.13.4 Antenna Mutual Coupling, Reaction Concept, and Antenna Measurements -- 6.14 Relation Between Antenna and Scattering Problems -- 6.14.1 Exterior Radiation by a Slot Aperture Antenna Configuration -- 6.14.2 Exterior Radiation by a Monopole Antenna Configuration -- 6.15 Radar Cross Section -- 6.16 Antenna Directive Gain -- 6.17 Field Decomposition Theorem -- References -- 7 Modal Techniques for the Analysis of Guided Waves, Resonant Cavities, and Periodic Structures -- 7.1 On Modal Analysis of Some Guided Wave Problems -- 7.2 Classification of Modal Fields in Uniform Guiding Structures -- 7.2.1 TEMz Guided waves -- 7.3 TMz Guided Waves -- 7.4 TEz Guided Waves -- 7.5 Modal Expansions in Closed Uniform Waveguides -- 7.5.1 TMz Modes -- 7.5.2 TEz Modes -- 7.5.3 Orthogonality of Modes in Closed Perfectly Conducting Uniform Waveguides -- 7.6 E ect of Losses in Closed Guided Wave Structures -- 7.7 Source Excited Uniform Closed Perfectly Conducting Waveguides -- 7.8 An Analysis of Some Closed Metallic Waveguides</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">7.8.1 Modes in a Parallel Plate Waveguide -- 7.8.2 Modes in a Rectangular Waveguide -- 7.8.3 Modes in a Circular Waveguide -- 7.8.4 Coaxial Waveguide -- 7.8.5 Obstacles and Discontinuities in Waveguides -- 7.8.6 Modal Propagation Past a Slot in a Waveguide -- 7.9 Closed and Open Waveguides Containing Penetrable Materials and Coatings -- 7.9.1 Material-Loaded Closed PEC Waveguide -- 7.9.2 Material Slab Waveguide -- 7.9.3 Grounded Material Slab Waveguide -- 7.9.4 The Goubau Line -- 7.9.5 Circular Cylindrical Optical Fiber Waveguides -- 7.10 Modal Analysis of Resonators -- 7.10.1 Rectangular Waveguide Cavity Resonator -- 7.10.2 Circular Waveguide Cavity Resonator -- 7.10.3 Dielectric Resonators -- 7.11 Excitation of Resonant Cavities -- 7.12 Modal Analysis of Periodic Arrays -- 7.12.1 Floquet Modal Analysis of an Infinite Planar Periodic Array of Electric Current Sources -- 7.12.2 Floquet Modal Analysis of an Infinite Planar Periodic Array of Current Sources Configured in a Skewed Grid -- 7.13 Higher-Order Floquet Modes and Associated Grating Lobe Circle Diagrams for Infinite Planar Periodic Arrays -- 7.13.1 Grating Lobe Circle Diagrams -- 7.14 On Waves Guided and Radiated by Periodic Structures -- 7.15 Scattering by a Planar Periodic Array -- 7.15.1 Analysis of the EM Plane Wave Scattering by an Infinite Periodic Slot Array in a Planar PEC Screen -- 7.16 Finite 1-D and 2-D Periodic Array of Sources -- 7.16.1 Analysis of Finite 1-D Periodic Arrays for the Case of Uniform Source Distribution and Far Zone Observation -- 7.16.2 Analysis of Finite 2-D Periodic Arrays for the Case of Uniform Distribution and Far Zone Observation -- 7.16.3 Floquet Modal Representation for Near and Far Fields of 1-D Nonuniform Finite Periodic Array Distributions</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">7.16.4 Floquet Modal Representation for Near and Far Fields of 2-D Nonuniform Planar Periodic Finite Array Distributions -- References -- 8 Green's Functions for the Analysis of One-Dimensional Source-Excited Wave Problems -- 8.1 Introduction to the Sturm-Liouville Form of Di erential Equation for 1-D Wave Problems -- 8.2 Formulation of the Solution to the Sturm-Liouville Problem via the 1-D Green's Function Approach -- 8.3 Conditions Under Which the Green's Function Is Symmetric -- 8.4 Construction of the Green's Function G(x|x') -- 8.4.1 General Procedure to Obtain G(x|x') -- 8.5 Alternative Simplified Construction of G(x|x') Valid for the SymmetricCase -- 8.6 On the Existence and Uniqueness of G(x|x') -- 8.7 Eigenfunction Expansion Representation for G(x|x') -- 8.8 Delta Function Completeness Relation and the Construction of Eigenfunctions from G(x|x') = U(x&lt -- )T(x)/W -- 8.9 Explicit Representation of G(x|x') Using Step Functions -- References -- 9 Applications of One-Dimensional Green's Function Approach for the Analysis of Single and Coupled Set of EM Source Excited Transmission Lines -- 9.1 Introduction -- 9.2 Analytical Formulation for a Single Transmission Line Made Up of Two Conductors -- 9.3 Wave Solution for the Two Conductor Lines When There Are No Impressed Sources Distributed Anywhere Within the Line -- 9.4 Wave Solution for the Case of Impressed Sources Placed Anywhere on a Two Conductor Line -- 9.5 Excitation of a Two Conductor Transmission Line by an Externally Incident lectromagnetic Wave -- 9.6 A Matrix Green's Function Approach for Analyzing a Set of Coupled Transmission Lines -- 9.7 Solution to the Special Case of Two Coupled Lines (N = 2) with Homogeneous Dirichlet or Neumann End Conditions -- 9.8 Development of the Multiport Impedance Matrix for a Set of Coupled Transmission 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| id | DE-604.BV048221332 |
| illustrated | Not Illustrated |
| index_date | 2024-07-03T19:50:32Z |
| indexdate | 2024-07-20T05:58:44Z |
| institution | BVB |
| isbn | 9781119810520 9781119810537 9781119810544 |
| language | English |
| oai_aleph_id | oai:aleph.bib-bvb.de:BVB01-033602069 |
| oclc_num | 1287132154 |
| open_access_boolean | |
| owner | DE-573 |
| owner_facet | DE-573 |
| physical | 1 Online-Ressource (xxiii, 1117 Seiten) |
| psigel | ZDB-30-PQE ZDB-35-WEL TUM_PDA_PQE |
| publishDate | 2022 |
| publishDateSearch | 2022 |
| publishDateSort | 2022 |
| publisher | John Wiley & Sons, Incorporated |
| record_format | marc |
| series2 | IEEE Press Series on Electromagnetic Wave Theory Ser |
| spelling | Pathak, Prabhakar H. 1942- Verfasser (DE-588)1266908013 aut Electromagnetic Radiation, Scattering, and Diffraction Prabhakar H. Pathak and Robert J. Burkholder Hoboken, NJ John Wiley & Sons, Incorporated 2022 ©2022 1 Online-Ressource (xxiii, 1117 Seiten) txt rdacontent c rdamedia cr rdacarrier IEEE Press Series on Electromagnetic Wave Theory Ser Description based on publisher supplied metadata and other sources Cover -- Title Page -- Copyright -- Contents -- About the Authors -- Preface -- Acknowledgments -- 1 Maxwell's Equations, Constitutive Relations, Wave Equation, and Polarization -- 1.1 Introductory Comments -- 1.2 Maxwell's Equations -- 1.3 Constitutive Relations -- 1.4 Frequency Domain Fields -- 1.5 Kramers-Kronig Relationship -- 1.6 Vector and Scalar Wave Equations -- 1.6.1 Vector Wave Equations for EM Fields -- 1.6.2 Scalar Wave Equations for EM Fields -- 1.7 Separable Solutions of the Source-Free Wave Equation in Rectangular Coordinates and for Isotropic Homogeneous Media. Plane Waves -- 1.8 Polarization of Plane Waves, Poincare Sphere, and Stokes Parameters -- 1.8.1 Polarization States -- 1.8.2 General Elliptical Polarization -- 1.8.3 Decomposition of a Polarization State into Circularly Polarized Components -- 1.8.4 Poincare Sphere for Describing Polarization States -- 1.9 Phase and Group Velocity -- 1.10 Separable Solutions of the Source-Free Wave Equation in Cylindrical and Spherical Coordinates and for Isotropic Homogeneous Media -- 1.10.1 Source-Free Cylindrical Wave Solutions -- 1.10.2 Source-Free Spherical Wave Solutions -- References -- 2 EM Boundary and Radiation Conditions -- 2.1 EM Field Behavior Across a Boundary Surface -- 2.2 Radiation Boundary Condition -- 2.3 Boundary Conditions at a Moving Interface -- 2.3.1 Nonrelativistic Moving Boundary Conditions -- 2.3.2 Derivation of the Nonrelativistic Field Transformations -- 2.3.3 EM Field Transformations Based on the Special Theory of Relativity -- 2.4 Constitutive Relations for a Moving Medium -- References -- 3 Plane Wave Propagation in Planar Layered Media -- 3.1 Introduction -- 3.2 Plane Wave Reection from a Planar Boundary Between Two Di erent Media -- 3.2.1 Perpendicular Polarization Case -- 3.2.2 Parallel Polarization Case -- 3.2.3 Brewster Angle θb 3.2.4 Critical Angle θc -- 3.2.5 Plane Wave Incident on a Lossy Half Space -- 3.2.6 Doppler Shift for Wave Reection from a Moving Mirror -- 3.3 Reection and Transmission of a Plane Wave Incident on a Planar Stratified Isotropic Medium Using a Transmission Matrix Approach -- 3.4 Plane Waves in Anisotropic Homogeneous Media -- 3.5 State Space Formulation for Waves in Planar Anisotropic Layered Media -- 3.5.1 Development of State Space Based Field Equations -- 3.5.2 Reection and Transmission of Plane Waves at the Interface Between Two Anisotropic Half Spaces -- 3.5.3 Transmission Type Matrix Analysis of Plane Waves in Multilayered Anisotropic Media -- References -- 4 Plane Wave Spectral Representation for EM Fields -- 4.1 Introduction -- 4.2 PWS Development -- References -- 5 Electromagnetic Potentials and Fields of Sources in Unbounded Regions -- 5.1 Introduction to Vector and Scalar Potentials -- 5.2 Construction of the Solution for Ā -- 5.3 Calculation of Fields from Potentials -- 5.4 Time Dependent Potentials for Sources and Fields in Unbounded Regions -- 5.5 Potentials and Fields of a Moving Point Charge -- 5.6 Cerenkov Radiation -- 5.7 Direct Calculation of Fields of Sources in Unbounded Regions Using a Dyadic Green's Function -- 5.7.1 Fields of Sources in Unbounded, Isotropic, Homogeneous Media in Terms of a Closed Form Representation of Green's Dyadic, G0 -- 5.7.2 On the Singular Nature of G0(rr) for Observation Points Within the Source Region -- 5.7.3 Representation of the Green's Dyadic G0 in Terms of an Integral in the Wavenumber (k) Space -- 5.7.4 Electromagnetic Radiation by a Source in a General Bianisotropic Medium Using a Green's Dyadic Ga in k-Space -- References -- 6 Electromagnetic Field Theorems and Related Topics -- 6.1 Conservation of Charge -- 6.2 Conservation of Power -- 6.3 Conservation of Momentum -- 6.4 Radiation Pressure 6.5 Duality Theorem -- 6.6 Reciprocity Theorems and Conservation of Reactions -- 6.6.1 The Lorentz Reciprocity Theorem -- 6.6.2 Reciprocity Theorem for Bianisotropic Media -- 6.7 Uniqueness Theorem -- 6.8 Image Theorems -- 6.9 Equivalence Theorems -- 6.9.1 Volume Equivalence Theorem for EM Scattering -- 6.9.2 A Surface Equivalence Theorem for EM Scattering -- 6.9.3 A Surface Equivalence Theorem for Antennas -- 6.10 Antenna Impedance -- 6.11 Antenna Equivalent Circuit -- 6.12 The Receiving Antenna Problem -- 6.13 Expressions for Antenna Mutual Coupling Based on Generalized Reciprocity Theorems -- 6.13.1 Circuit Form of the Reciprocity Theorem for Antenna Mutual Coupling -- 6.13.2 A Mixed Circuit Field Form of a Generalized Reciprocity Theorem for Antenna Mutual Coupling -- 6.13.3 A Mutual Admittance Expression for Slot Antennas -- 6.13.4 Antenna Mutual Coupling, Reaction Concept, and Antenna Measurements -- 6.14 Relation Between Antenna and Scattering Problems -- 6.14.1 Exterior Radiation by a Slot Aperture Antenna Configuration -- 6.14.2 Exterior Radiation by a Monopole Antenna Configuration -- 6.15 Radar Cross Section -- 6.16 Antenna Directive Gain -- 6.17 Field Decomposition Theorem -- References -- 7 Modal Techniques for the Analysis of Guided Waves, Resonant Cavities, and Periodic Structures -- 7.1 On Modal Analysis of Some Guided Wave Problems -- 7.2 Classification of Modal Fields in Uniform Guiding Structures -- 7.2.1 TEMz Guided waves -- 7.3 TMz Guided Waves -- 7.4 TEz Guided Waves -- 7.5 Modal Expansions in Closed Uniform Waveguides -- 7.5.1 TMz Modes -- 7.5.2 TEz Modes -- 7.5.3 Orthogonality of Modes in Closed Perfectly Conducting Uniform Waveguides -- 7.6 E ect of Losses in Closed Guided Wave Structures -- 7.7 Source Excited Uniform Closed Perfectly Conducting Waveguides -- 7.8 An Analysis of Some Closed Metallic Waveguides 7.8.1 Modes in a Parallel Plate Waveguide -- 7.8.2 Modes in a Rectangular Waveguide -- 7.8.3 Modes in a Circular Waveguide -- 7.8.4 Coaxial Waveguide -- 7.8.5 Obstacles and Discontinuities in Waveguides -- 7.8.6 Modal Propagation Past a Slot in a Waveguide -- 7.9 Closed and Open Waveguides Containing Penetrable Materials and Coatings -- 7.9.1 Material-Loaded Closed PEC Waveguide -- 7.9.2 Material Slab Waveguide -- 7.9.3 Grounded Material Slab Waveguide -- 7.9.4 The Goubau Line -- 7.9.5 Circular Cylindrical Optical Fiber Waveguides -- 7.10 Modal Analysis of Resonators -- 7.10.1 Rectangular Waveguide Cavity Resonator -- 7.10.2 Circular Waveguide Cavity Resonator -- 7.10.3 Dielectric Resonators -- 7.11 Excitation of Resonant Cavities -- 7.12 Modal Analysis of Periodic Arrays -- 7.12.1 Floquet Modal Analysis of an Infinite Planar Periodic Array of Electric Current Sources -- 7.12.2 Floquet Modal Analysis of an Infinite Planar Periodic Array of Current Sources Configured in a Skewed Grid -- 7.13 Higher-Order Floquet Modes and Associated Grating Lobe Circle Diagrams for Infinite Planar Periodic Arrays -- 7.13.1 Grating Lobe Circle Diagrams -- 7.14 On Waves Guided and Radiated by Periodic Structures -- 7.15 Scattering by a Planar Periodic Array -- 7.15.1 Analysis of the EM Plane Wave Scattering by an Infinite Periodic Slot Array in a Planar PEC Screen -- 7.16 Finite 1-D and 2-D Periodic Array of Sources -- 7.16.1 Analysis of Finite 1-D Periodic Arrays for the Case of Uniform Source Distribution and Far Zone Observation -- 7.16.2 Analysis of Finite 2-D Periodic Arrays for the Case of Uniform Distribution and Far Zone Observation -- 7.16.3 Floquet Modal Representation for Near and Far Fields of 1-D Nonuniform Finite Periodic Array Distributions 7.16.4 Floquet Modal Representation for Near and Far Fields of 2-D Nonuniform Planar Periodic Finite Array Distributions -- References -- 8 Green's Functions for the Analysis of One-Dimensional Source-Excited Wave Problems -- 8.1 Introduction to the Sturm-Liouville Form of Di erential Equation for 1-D Wave Problems -- 8.2 Formulation of the Solution to the Sturm-Liouville Problem via the 1-D Green's Function Approach -- 8.3 Conditions Under Which the Green's Function Is Symmetric -- 8.4 Construction of the Green's Function G(x|x') -- 8.4.1 General Procedure to Obtain G(x|x') -- 8.5 Alternative Simplified Construction of G(x|x') Valid for the SymmetricCase -- 8.6 On the Existence and Uniqueness of G(x|x') -- 8.7 Eigenfunction Expansion Representation for G(x|x') -- 8.8 Delta Function Completeness Relation and the Construction of Eigenfunctions from G(x|x') = U(x< -- )T(x)/W -- 8.9 Explicit Representation of G(x|x') Using Step Functions -- References -- 9 Applications of One-Dimensional Green's Function Approach for the Analysis of Single and Coupled Set of EM Source Excited Transmission Lines -- 9.1 Introduction -- 9.2 Analytical Formulation for a Single Transmission Line Made Up of Two Conductors -- 9.3 Wave Solution for the Two Conductor Lines When There Are No Impressed Sources Distributed Anywhere Within the Line -- 9.4 Wave Solution for the Case of Impressed Sources Placed Anywhere on a Two Conductor Line -- 9.5 Excitation of a Two Conductor Transmission Line by an Externally Incident lectromagnetic Wave -- 9.6 A Matrix Green's Function Approach for Analyzing a Set of Coupled Transmission Lines -- 9.7 Solution to the Special Case of Two Coupled Lines (N = 2) with Homogeneous Dirichlet or Neumann End Conditions -- 9.8 Development of the Multiport Impedance Matrix for a Set of Coupled Transmission Lines 9.9 Coupled Transmission Line Problems with Voltage Sources and Load Impedances at the End Terminals Burkholder, Robert J. Sonstige (DE-588)1266908706 oth Erscheint auch als Druck-Ausgabe Pathak, Prabhakar H. Electromagnetic Radiation, Scattering, and Diffraction Newark : John Wiley & Sons, Incorporated,c2021 978-1-119-81051-3 |
| spellingShingle | Pathak, Prabhakar H. 1942- Electromagnetic Radiation, Scattering, and Diffraction Cover -- Title Page -- Copyright -- Contents -- About the Authors -- Preface -- Acknowledgments -- 1 Maxwell's Equations, Constitutive Relations, Wave Equation, and Polarization -- 1.1 Introductory Comments -- 1.2 Maxwell's Equations -- 1.3 Constitutive Relations -- 1.4 Frequency Domain Fields -- 1.5 Kramers-Kronig Relationship -- 1.6 Vector and Scalar Wave Equations -- 1.6.1 Vector Wave Equations for EM Fields -- 1.6.2 Scalar Wave Equations for EM Fields -- 1.7 Separable Solutions of the Source-Free Wave Equation in Rectangular Coordinates and for Isotropic Homogeneous Media. Plane Waves -- 1.8 Polarization of Plane Waves, Poincare Sphere, and Stokes Parameters -- 1.8.1 Polarization States -- 1.8.2 General Elliptical Polarization -- 1.8.3 Decomposition of a Polarization State into Circularly Polarized Components -- 1.8.4 Poincare Sphere for Describing Polarization States -- 1.9 Phase and Group Velocity -- 1.10 Separable Solutions of the Source-Free Wave Equation in Cylindrical and Spherical Coordinates and for Isotropic Homogeneous Media -- 1.10.1 Source-Free Cylindrical Wave Solutions -- 1.10.2 Source-Free Spherical Wave Solutions -- References -- 2 EM Boundary and Radiation Conditions -- 2.1 EM Field Behavior Across a Boundary Surface -- 2.2 Radiation Boundary Condition -- 2.3 Boundary Conditions at a Moving Interface -- 2.3.1 Nonrelativistic Moving Boundary Conditions -- 2.3.2 Derivation of the Nonrelativistic Field Transformations -- 2.3.3 EM Field Transformations Based on the Special Theory of Relativity -- 2.4 Constitutive Relations for a Moving Medium -- References -- 3 Plane Wave Propagation in Planar Layered Media -- 3.1 Introduction -- 3.2 Plane Wave Reection from a Planar Boundary Between Two Di erent Media -- 3.2.1 Perpendicular Polarization Case -- 3.2.2 Parallel Polarization Case -- 3.2.3 Brewster Angle θb 3.2.4 Critical Angle θc -- 3.2.5 Plane Wave Incident on a Lossy Half Space -- 3.2.6 Doppler Shift for Wave Reection from a Moving Mirror -- 3.3 Reection and Transmission of a Plane Wave Incident on a Planar Stratified Isotropic Medium Using a Transmission Matrix Approach -- 3.4 Plane Waves in Anisotropic Homogeneous Media -- 3.5 State Space Formulation for Waves in Planar Anisotropic Layered Media -- 3.5.1 Development of State Space Based Field Equations -- 3.5.2 Reection and Transmission of Plane Waves at the Interface Between Two Anisotropic Half Spaces -- 3.5.3 Transmission Type Matrix Analysis of Plane Waves in Multilayered Anisotropic Media -- References -- 4 Plane Wave Spectral Representation for EM Fields -- 4.1 Introduction -- 4.2 PWS Development -- References -- 5 Electromagnetic Potentials and Fields of Sources in Unbounded Regions -- 5.1 Introduction to Vector and Scalar Potentials -- 5.2 Construction of the Solution for Ā -- 5.3 Calculation of Fields from Potentials -- 5.4 Time Dependent Potentials for Sources and Fields in Unbounded Regions -- 5.5 Potentials and Fields of a Moving Point Charge -- 5.6 Cerenkov Radiation -- 5.7 Direct Calculation of Fields of Sources in Unbounded Regions Using a Dyadic Green's Function -- 5.7.1 Fields of Sources in Unbounded, Isotropic, Homogeneous Media in Terms of a Closed Form Representation of Green's Dyadic, G0 -- 5.7.2 On the Singular Nature of G0(rr) for Observation Points Within the Source Region -- 5.7.3 Representation of the Green's Dyadic G0 in Terms of an Integral in the Wavenumber (k) Space -- 5.7.4 Electromagnetic Radiation by a Source in a General Bianisotropic Medium Using a Green's Dyadic Ga in k-Space -- References -- 6 Electromagnetic Field Theorems and Related Topics -- 6.1 Conservation of Charge -- 6.2 Conservation of Power -- 6.3 Conservation of Momentum -- 6.4 Radiation Pressure 6.5 Duality Theorem -- 6.6 Reciprocity Theorems and Conservation of Reactions -- 6.6.1 The Lorentz Reciprocity Theorem -- 6.6.2 Reciprocity Theorem for Bianisotropic Media -- 6.7 Uniqueness Theorem -- 6.8 Image Theorems -- 6.9 Equivalence Theorems -- 6.9.1 Volume Equivalence Theorem for EM Scattering -- 6.9.2 A Surface Equivalence Theorem for EM Scattering -- 6.9.3 A Surface Equivalence Theorem for Antennas -- 6.10 Antenna Impedance -- 6.11 Antenna Equivalent Circuit -- 6.12 The Receiving Antenna Problem -- 6.13 Expressions for Antenna Mutual Coupling Based on Generalized Reciprocity Theorems -- 6.13.1 Circuit Form of the Reciprocity Theorem for Antenna Mutual Coupling -- 6.13.2 A Mixed Circuit Field Form of a Generalized Reciprocity Theorem for Antenna Mutual Coupling -- 6.13.3 A Mutual Admittance Expression for Slot Antennas -- 6.13.4 Antenna Mutual Coupling, Reaction Concept, and Antenna Measurements -- 6.14 Relation Between Antenna and Scattering Problems -- 6.14.1 Exterior Radiation by a Slot Aperture Antenna Configuration -- 6.14.2 Exterior Radiation by a Monopole Antenna Configuration -- 6.15 Radar Cross Section -- 6.16 Antenna Directive Gain -- 6.17 Field Decomposition Theorem -- References -- 7 Modal Techniques for the Analysis of Guided Waves, Resonant Cavities, and Periodic Structures -- 7.1 On Modal Analysis of Some Guided Wave Problems -- 7.2 Classification of Modal Fields in Uniform Guiding Structures -- 7.2.1 TEMz Guided waves -- 7.3 TMz Guided Waves -- 7.4 TEz Guided Waves -- 7.5 Modal Expansions in Closed Uniform Waveguides -- 7.5.1 TMz Modes -- 7.5.2 TEz Modes -- 7.5.3 Orthogonality of Modes in Closed Perfectly Conducting Uniform Waveguides -- 7.6 E ect of Losses in Closed Guided Wave Structures -- 7.7 Source Excited Uniform Closed Perfectly Conducting Waveguides -- 7.8 An Analysis of Some Closed Metallic Waveguides 7.8.1 Modes in a Parallel Plate Waveguide -- 7.8.2 Modes in a Rectangular Waveguide -- 7.8.3 Modes in a Circular Waveguide -- 7.8.4 Coaxial Waveguide -- 7.8.5 Obstacles and Discontinuities in Waveguides -- 7.8.6 Modal Propagation Past a Slot in a Waveguide -- 7.9 Closed and Open Waveguides Containing Penetrable Materials and Coatings -- 7.9.1 Material-Loaded Closed PEC Waveguide -- 7.9.2 Material Slab Waveguide -- 7.9.3 Grounded Material Slab Waveguide -- 7.9.4 The Goubau Line -- 7.9.5 Circular Cylindrical Optical Fiber Waveguides -- 7.10 Modal Analysis of Resonators -- 7.10.1 Rectangular Waveguide Cavity Resonator -- 7.10.2 Circular Waveguide Cavity Resonator -- 7.10.3 Dielectric Resonators -- 7.11 Excitation of Resonant Cavities -- 7.12 Modal Analysis of Periodic Arrays -- 7.12.1 Floquet Modal Analysis of an Infinite Planar Periodic Array of Electric Current Sources -- 7.12.2 Floquet Modal Analysis of an Infinite Planar Periodic Array of Current Sources Configured in a Skewed Grid -- 7.13 Higher-Order Floquet Modes and Associated Grating Lobe Circle Diagrams for Infinite Planar Periodic Arrays -- 7.13.1 Grating Lobe Circle Diagrams -- 7.14 On Waves Guided and Radiated by Periodic Structures -- 7.15 Scattering by a Planar Periodic Array -- 7.15.1 Analysis of the EM Plane Wave Scattering by an Infinite Periodic Slot Array in a Planar PEC Screen -- 7.16 Finite 1-D and 2-D Periodic Array of Sources -- 7.16.1 Analysis of Finite 1-D Periodic Arrays for the Case of Uniform Source Distribution and Far Zone Observation -- 7.16.2 Analysis of Finite 2-D Periodic Arrays for the Case of Uniform Distribution and Far Zone Observation -- 7.16.3 Floquet Modal Representation for Near and Far Fields of 1-D Nonuniform Finite Periodic Array Distributions 7.16.4 Floquet Modal Representation for Near and Far Fields of 2-D Nonuniform Planar Periodic Finite Array Distributions -- References -- 8 Green's Functions for the Analysis of One-Dimensional Source-Excited Wave Problems -- 8.1 Introduction to the Sturm-Liouville Form of Di erential Equation for 1-D Wave Problems -- 8.2 Formulation of the Solution to the Sturm-Liouville Problem via the 1-D Green's Function Approach -- 8.3 Conditions Under Which the Green's Function Is Symmetric -- 8.4 Construction of the Green's Function G(x|x') -- 8.4.1 General Procedure to Obtain G(x|x') -- 8.5 Alternative Simplified Construction of G(x|x') Valid for the SymmetricCase -- 8.6 On the Existence and Uniqueness of G(x|x') -- 8.7 Eigenfunction Expansion Representation for G(x|x') -- 8.8 Delta Function Completeness Relation and the Construction of Eigenfunctions from G(x|x') = U(x< -- )T(x)/W -- 8.9 Explicit Representation of G(x|x') Using Step Functions -- References -- 9 Applications of One-Dimensional Green's Function Approach for the Analysis of Single and Coupled Set of EM Source Excited Transmission Lines -- 9.1 Introduction -- 9.2 Analytical Formulation for a Single Transmission Line Made Up of Two Conductors -- 9.3 Wave Solution for the Two Conductor Lines When There Are No Impressed Sources Distributed Anywhere Within the Line -- 9.4 Wave Solution for the Case of Impressed Sources Placed Anywhere on a Two Conductor Line -- 9.5 Excitation of a Two Conductor Transmission Line by an Externally Incident lectromagnetic Wave -- 9.6 A Matrix Green's Function Approach for Analyzing a Set of Coupled Transmission Lines -- 9.7 Solution to the Special Case of Two Coupled Lines (N = 2) with Homogeneous Dirichlet or Neumann End Conditions -- 9.8 Development of the Multiport Impedance Matrix for a Set of Coupled Transmission Lines 9.9 Coupled Transmission Line Problems with Voltage Sources and Load Impedances at the End Terminals |
| title | Electromagnetic Radiation, Scattering, and Diffraction |
| title_auth | Electromagnetic Radiation, Scattering, and Diffraction |
| title_exact_search | Electromagnetic Radiation, Scattering, and Diffraction |
| title_exact_search_txtP | Electromagnetic Radiation, Scattering, and Diffraction |
| title_full | Electromagnetic Radiation, Scattering, and Diffraction Prabhakar H. Pathak and Robert J. Burkholder |
| title_fullStr | Electromagnetic Radiation, Scattering, and Diffraction Prabhakar H. Pathak and Robert J. Burkholder |
| title_full_unstemmed | Electromagnetic Radiation, Scattering, and Diffraction Prabhakar H. Pathak and Robert J. Burkholder |
| title_short | Electromagnetic Radiation, Scattering, and Diffraction |
| title_sort | electromagnetic radiation scattering and diffraction |
| work_keys_str_mv | AT pathakprabhakarh electromagneticradiationscatteringanddiffraction AT burkholderrobertj electromagneticradiationscatteringanddiffraction |