L. B. Felsen
Radiation and Scattering of Waves
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L. B. Felsen
Radiation and Scattering of Waves
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As relevant today as it was when it was first published 20 years ago, this book is a classic in the field. Nowhere else can you find more complete coverage of radiation and scattering of waves. The chapter: Asympotic Evaluation of Integrals is considered the definitive source for asympotic techniques.
This book is essential reading for engineers, physicists and others involved in the fields of electromagnetics and acoustics. It is also an indispensable reference for advanced engineering courses.
As relevant today as it was when it was first published 20 years ago, this book is a classic in the field. Nowhere else can you find more complete coverage of radiation and scattering of waves. The chapter: Asympotic Evaluation of Integrals is considered the definitive source for asympotic techniques.
This book is essential reading for engineers, physicists and others involved in the fields of electromagnetics and acoustics. It is also an indispensable reference for advanced engineering courses.
This book is essential reading for engineers, physicists and others involved in the fields of electromagnetics and acoustics. It is also an indispensable reference for advanced engineering courses.
Produktdetails
- Produktdetails
- IEEE/OUP Series on Electromagnetic Wave Theory (formerly IEEE only), Series Editor: Donald G. Dudley
- Verlag: Wiley & Sons
- 1. Auflage
- Seitenzahl: 924
- Erscheinungstermin: 15. Januar 1994
- Englisch
- Abmessung: 236mm x 162mm x 54mm
- Gewicht: 1247g
- ISBN-13: 9780780310889
- ISBN-10: 0780310888
- Artikelnr.: 14918781
- IEEE/OUP Series on Electromagnetic Wave Theory (formerly IEEE only), Series Editor: Donald G. Dudley
- Verlag: Wiley & Sons
- 1. Auflage
- Seitenzahl: 924
- Erscheinungstermin: 15. Januar 1994
- Englisch
- Abmessung: 236mm x 162mm x 54mm
- Gewicht: 1247g
- ISBN-13: 9780780310889
- ISBN-10: 0780310888
- Artikelnr.: 14918781
Leopold B. Felsen was a physicist known for studies of Electromagnetism and wave-based disciplines. He had to flee Germany at 16 due to the Nazis. He has fundamental contributions to electromagnetic field analysis. Nathan Marcuvitz, was an American electrical engineer, physicist, and educator who worked in the fields of microwave and electromagnetic theory. He was head of the experimental group of the Radiation Laboratory. He was a member of the National Academy of Engineering.
FOREWORD. PERSPECTIVES ON THE REISSUE. 1. SPACE- AND TIME-DEPENDENT LINEAR
FIELDS. 1.1 Formulation of Vector Field and Scalar Potential Problems. 1.2
Plane Wave Field Representations. 1.3 Guided Wave (Oscillatory)
Representations in Time. 1.4 Guided Wave Representations in Space. 1.5
Reduced Electromagnetic Field Equations. 1.6 Ray-Optic Approximations of
Integral Representations. 1.7 Rap-Optic Approximations for Differential
Equations. 2. NETWORK FORMALISM FOR TIME-HARMONIC ELECTROMAGNETIC FIELDS IN
UNIFORM AND SPHERICAL WAVEGUIDE REGIONS. 2.1 Introduction. 2.2 Derivation
of Transmission-Line Equations in Uniform Regions. 2.3 Scalarization and
Modal Representation of Dyadic Green's Functions in Uniform Regions. 2.4
Solution of Uniform Transmission-Line Equations (Network Analysis). 2.5
Derivation of Transmission-Line Equations in Spherical Regions. 2.6
Scalarization and Modal Representation of Dyadic Green's Functions in
Spherical Regions. 2.7 Solution of Spherical Transmission-Line Equations
(Network Analysis). 3. MODE FUNCTIONS IN CLOSED AND OPEN WAVEGUIDES. 3.1
Introduction. 3.2 Classical Evaluation of Mode Functions. 3.3
Characteristic Green's Function (Resolvent) Procedure and Alternative
Representations. 3.4 One-Dimensional Characteristic Green's Function and
Eigenf unction Solutions. 3.5 Approximate Methods for Solving the
Non-Uniform Transmission-Line Equations. 3.6 Application to Various
Inhomogeneity Profiles. 4. ASYMPTOTIC EVALUATION OF INTEGRALS. 4.1 General
Considerations. 4.2 Isolated First-Order Saddle Points. 4.3 Isolated Saddle
Points of Higher Order. 4.4 First-Order Saddle Point and Nearby
Singularities. 4.5 Nearby First-Order Saddle Points. 4.6 Saddle Points Near
an Endpoint. 4.7 Multiple Integrals. 4.8 Integration Around a Branch Point.
5. FIELDS IN PLANE-STRATIFIED REGIONS. 5.1 Introduction. 5.2 Field
Representations in Regions with Piece wise Constant Properties. 5.3
Integration Techniques. 5.4 Sources in an Unbounded Dielectric. 5.5 Sources
in the Presence of a Semi-Infinite Dielectric Medium. 5.6 Time-Harmonic
Sources in the Presence of a Dielectric Slab. 5.7 Time-Harmonic Sources in
the Presence of a Constant-Impedance Surface. 5.8 Sources in the Presence
of Media with Continuous Planar Stratification-Arbitrary Profiles. 5.9
Sources in the Presence of Media with Continuous Planar
Stratification-Special Profiles. 6. FIELDS IN CYLINDRICAL AND SPHERICAL
REGIONS. 6.1 Distinctive Field Characteristics. 6.2 Green's Function
Representations in Cylindrical Regions. 6.3 Wedge-Type
Problems--Integration Techniques. 6.4 Perfectly Absorbing Wedge. 6.5
Perfectly Conducting Wedge and Half Plane. 6.6 Wedge with Variable
Impedance Walls. 6.7 Diffraction by a Circular Cylinder. 6.8 Fields in
Spherical Regions. 7. FIELDS IN UNIAXIALLY ANISOTROPIC REGIONS. 7.1
Introduction. 7.2 Network Formulation of Field Problem. 7.3 Sources in
Unbounded Media. 7.4 Diffraction by Structures Embedded in an Infinite
Homogeneous Plasma. 7.5 Radiation from a Homogeneous Plasma Half Space. 8.
FIELDS IN ANISOTROPIC REGIONS. 8.1 Introduction. 8.2 Guided Wave
Representation in Anisotropic Media (Reduced Formulation). 8.3 Guided Waves
in a Cold Magnetoplasma (Guide Axis Parallel to Gyrotropic Axis). 8.4
Guided Waves in a Cold Magnetoplasma (Guide Axis Perpendicular to
Gyrotropic Axis). SUBJECT INDEX. AUTHOR INDEX.
FIELDS. 1.1 Formulation of Vector Field and Scalar Potential Problems. 1.2
Plane Wave Field Representations. 1.3 Guided Wave (Oscillatory)
Representations in Time. 1.4 Guided Wave Representations in Space. 1.5
Reduced Electromagnetic Field Equations. 1.6 Ray-Optic Approximations of
Integral Representations. 1.7 Rap-Optic Approximations for Differential
Equations. 2. NETWORK FORMALISM FOR TIME-HARMONIC ELECTROMAGNETIC FIELDS IN
UNIFORM AND SPHERICAL WAVEGUIDE REGIONS. 2.1 Introduction. 2.2 Derivation
of Transmission-Line Equations in Uniform Regions. 2.3 Scalarization and
Modal Representation of Dyadic Green's Functions in Uniform Regions. 2.4
Solution of Uniform Transmission-Line Equations (Network Analysis). 2.5
Derivation of Transmission-Line Equations in Spherical Regions. 2.6
Scalarization and Modal Representation of Dyadic Green's Functions in
Spherical Regions. 2.7 Solution of Spherical Transmission-Line Equations
(Network Analysis). 3. MODE FUNCTIONS IN CLOSED AND OPEN WAVEGUIDES. 3.1
Introduction. 3.2 Classical Evaluation of Mode Functions. 3.3
Characteristic Green's Function (Resolvent) Procedure and Alternative
Representations. 3.4 One-Dimensional Characteristic Green's Function and
Eigenf unction Solutions. 3.5 Approximate Methods for Solving the
Non-Uniform Transmission-Line Equations. 3.6 Application to Various
Inhomogeneity Profiles. 4. ASYMPTOTIC EVALUATION OF INTEGRALS. 4.1 General
Considerations. 4.2 Isolated First-Order Saddle Points. 4.3 Isolated Saddle
Points of Higher Order. 4.4 First-Order Saddle Point and Nearby
Singularities. 4.5 Nearby First-Order Saddle Points. 4.6 Saddle Points Near
an Endpoint. 4.7 Multiple Integrals. 4.8 Integration Around a Branch Point.
5. FIELDS IN PLANE-STRATIFIED REGIONS. 5.1 Introduction. 5.2 Field
Representations in Regions with Piece wise Constant Properties. 5.3
Integration Techniques. 5.4 Sources in an Unbounded Dielectric. 5.5 Sources
in the Presence of a Semi-Infinite Dielectric Medium. 5.6 Time-Harmonic
Sources in the Presence of a Dielectric Slab. 5.7 Time-Harmonic Sources in
the Presence of a Constant-Impedance Surface. 5.8 Sources in the Presence
of Media with Continuous Planar Stratification-Arbitrary Profiles. 5.9
Sources in the Presence of Media with Continuous Planar
Stratification-Special Profiles. 6. FIELDS IN CYLINDRICAL AND SPHERICAL
REGIONS. 6.1 Distinctive Field Characteristics. 6.2 Green's Function
Representations in Cylindrical Regions. 6.3 Wedge-Type
Problems--Integration Techniques. 6.4 Perfectly Absorbing Wedge. 6.5
Perfectly Conducting Wedge and Half Plane. 6.6 Wedge with Variable
Impedance Walls. 6.7 Diffraction by a Circular Cylinder. 6.8 Fields in
Spherical Regions. 7. FIELDS IN UNIAXIALLY ANISOTROPIC REGIONS. 7.1
Introduction. 7.2 Network Formulation of Field Problem. 7.3 Sources in
Unbounded Media. 7.4 Diffraction by Structures Embedded in an Infinite
Homogeneous Plasma. 7.5 Radiation from a Homogeneous Plasma Half Space. 8.
FIELDS IN ANISOTROPIC REGIONS. 8.1 Introduction. 8.2 Guided Wave
Representation in Anisotropic Media (Reduced Formulation). 8.3 Guided Waves
in a Cold Magnetoplasma (Guide Axis Parallel to Gyrotropic Axis). 8.4
Guided Waves in a Cold Magnetoplasma (Guide Axis Perpendicular to
Gyrotropic Axis). SUBJECT INDEX. AUTHOR INDEX.
FOREWORD. PERSPECTIVES ON THE REISSUE. 1. SPACE- AND TIME-DEPENDENT LINEAR
FIELDS. 1.1 Formulation of Vector Field and Scalar Potential Problems. 1.2
Plane Wave Field Representations. 1.3 Guided Wave (Oscillatory)
Representations in Time. 1.4 Guided Wave Representations in Space. 1.5
Reduced Electromagnetic Field Equations. 1.6 Ray-Optic Approximations of
Integral Representations. 1.7 Rap-Optic Approximations for Differential
Equations. 2. NETWORK FORMALISM FOR TIME-HARMONIC ELECTROMAGNETIC FIELDS IN
UNIFORM AND SPHERICAL WAVEGUIDE REGIONS. 2.1 Introduction. 2.2 Derivation
of Transmission-Line Equations in Uniform Regions. 2.3 Scalarization and
Modal Representation of Dyadic Green's Functions in Uniform Regions. 2.4
Solution of Uniform Transmission-Line Equations (Network Analysis). 2.5
Derivation of Transmission-Line Equations in Spherical Regions. 2.6
Scalarization and Modal Representation of Dyadic Green's Functions in
Spherical Regions. 2.7 Solution of Spherical Transmission-Line Equations
(Network Analysis). 3. MODE FUNCTIONS IN CLOSED AND OPEN WAVEGUIDES. 3.1
Introduction. 3.2 Classical Evaluation of Mode Functions. 3.3
Characteristic Green's Function (Resolvent) Procedure and Alternative
Representations. 3.4 One-Dimensional Characteristic Green's Function and
Eigenf unction Solutions. 3.5 Approximate Methods for Solving the
Non-Uniform Transmission-Line Equations. 3.6 Application to Various
Inhomogeneity Profiles. 4. ASYMPTOTIC EVALUATION OF INTEGRALS. 4.1 General
Considerations. 4.2 Isolated First-Order Saddle Points. 4.3 Isolated Saddle
Points of Higher Order. 4.4 First-Order Saddle Point and Nearby
Singularities. 4.5 Nearby First-Order Saddle Points. 4.6 Saddle Points Near
an Endpoint. 4.7 Multiple Integrals. 4.8 Integration Around a Branch Point.
5. FIELDS IN PLANE-STRATIFIED REGIONS. 5.1 Introduction. 5.2 Field
Representations in Regions with Piece wise Constant Properties. 5.3
Integration Techniques. 5.4 Sources in an Unbounded Dielectric. 5.5 Sources
in the Presence of a Semi-Infinite Dielectric Medium. 5.6 Time-Harmonic
Sources in the Presence of a Dielectric Slab. 5.7 Time-Harmonic Sources in
the Presence of a Constant-Impedance Surface. 5.8 Sources in the Presence
of Media with Continuous Planar Stratification-Arbitrary Profiles. 5.9
Sources in the Presence of Media with Continuous Planar
Stratification-Special Profiles. 6. FIELDS IN CYLINDRICAL AND SPHERICAL
REGIONS. 6.1 Distinctive Field Characteristics. 6.2 Green's Function
Representations in Cylindrical Regions. 6.3 Wedge-Type
Problems--Integration Techniques. 6.4 Perfectly Absorbing Wedge. 6.5
Perfectly Conducting Wedge and Half Plane. 6.6 Wedge with Variable
Impedance Walls. 6.7 Diffraction by a Circular Cylinder. 6.8 Fields in
Spherical Regions. 7. FIELDS IN UNIAXIALLY ANISOTROPIC REGIONS. 7.1
Introduction. 7.2 Network Formulation of Field Problem. 7.3 Sources in
Unbounded Media. 7.4 Diffraction by Structures Embedded in an Infinite
Homogeneous Plasma. 7.5 Radiation from a Homogeneous Plasma Half Space. 8.
FIELDS IN ANISOTROPIC REGIONS. 8.1 Introduction. 8.2 Guided Wave
Representation in Anisotropic Media (Reduced Formulation). 8.3 Guided Waves
in a Cold Magnetoplasma (Guide Axis Parallel to Gyrotropic Axis). 8.4
Guided Waves in a Cold Magnetoplasma (Guide Axis Perpendicular to
Gyrotropic Axis). SUBJECT INDEX. AUTHOR INDEX.
FIELDS. 1.1 Formulation of Vector Field and Scalar Potential Problems. 1.2
Plane Wave Field Representations. 1.3 Guided Wave (Oscillatory)
Representations in Time. 1.4 Guided Wave Representations in Space. 1.5
Reduced Electromagnetic Field Equations. 1.6 Ray-Optic Approximations of
Integral Representations. 1.7 Rap-Optic Approximations for Differential
Equations. 2. NETWORK FORMALISM FOR TIME-HARMONIC ELECTROMAGNETIC FIELDS IN
UNIFORM AND SPHERICAL WAVEGUIDE REGIONS. 2.1 Introduction. 2.2 Derivation
of Transmission-Line Equations in Uniform Regions. 2.3 Scalarization and
Modal Representation of Dyadic Green's Functions in Uniform Regions. 2.4
Solution of Uniform Transmission-Line Equations (Network Analysis). 2.5
Derivation of Transmission-Line Equations in Spherical Regions. 2.6
Scalarization and Modal Representation of Dyadic Green's Functions in
Spherical Regions. 2.7 Solution of Spherical Transmission-Line Equations
(Network Analysis). 3. MODE FUNCTIONS IN CLOSED AND OPEN WAVEGUIDES. 3.1
Introduction. 3.2 Classical Evaluation of Mode Functions. 3.3
Characteristic Green's Function (Resolvent) Procedure and Alternative
Representations. 3.4 One-Dimensional Characteristic Green's Function and
Eigenf unction Solutions. 3.5 Approximate Methods for Solving the
Non-Uniform Transmission-Line Equations. 3.6 Application to Various
Inhomogeneity Profiles. 4. ASYMPTOTIC EVALUATION OF INTEGRALS. 4.1 General
Considerations. 4.2 Isolated First-Order Saddle Points. 4.3 Isolated Saddle
Points of Higher Order. 4.4 First-Order Saddle Point and Nearby
Singularities. 4.5 Nearby First-Order Saddle Points. 4.6 Saddle Points Near
an Endpoint. 4.7 Multiple Integrals. 4.8 Integration Around a Branch Point.
5. FIELDS IN PLANE-STRATIFIED REGIONS. 5.1 Introduction. 5.2 Field
Representations in Regions with Piece wise Constant Properties. 5.3
Integration Techniques. 5.4 Sources in an Unbounded Dielectric. 5.5 Sources
in the Presence of a Semi-Infinite Dielectric Medium. 5.6 Time-Harmonic
Sources in the Presence of a Dielectric Slab. 5.7 Time-Harmonic Sources in
the Presence of a Constant-Impedance Surface. 5.8 Sources in the Presence
of Media with Continuous Planar Stratification-Arbitrary Profiles. 5.9
Sources in the Presence of Media with Continuous Planar
Stratification-Special Profiles. 6. FIELDS IN CYLINDRICAL AND SPHERICAL
REGIONS. 6.1 Distinctive Field Characteristics. 6.2 Green's Function
Representations in Cylindrical Regions. 6.3 Wedge-Type
Problems--Integration Techniques. 6.4 Perfectly Absorbing Wedge. 6.5
Perfectly Conducting Wedge and Half Plane. 6.6 Wedge with Variable
Impedance Walls. 6.7 Diffraction by a Circular Cylinder. 6.8 Fields in
Spherical Regions. 7. FIELDS IN UNIAXIALLY ANISOTROPIC REGIONS. 7.1
Introduction. 7.2 Network Formulation of Field Problem. 7.3 Sources in
Unbounded Media. 7.4 Diffraction by Structures Embedded in an Infinite
Homogeneous Plasma. 7.5 Radiation from a Homogeneous Plasma Half Space. 8.
FIELDS IN ANISOTROPIC REGIONS. 8.1 Introduction. 8.2 Guided Wave
Representation in Anisotropic Media (Reduced Formulation). 8.3 Guided Waves
in a Cold Magnetoplasma (Guide Axis Parallel to Gyrotropic Axis). 8.4
Guided Waves in a Cold Magnetoplasma (Guide Axis Perpendicular to
Gyrotropic Axis). SUBJECT INDEX. AUTHOR INDEX.