Wen Geyi
Foundations of Applied Electrodynamics (eBook, PDF)
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Wen Geyi
Foundations of Applied Electrodynamics (eBook, PDF)
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Foundations of Applied Electrodynamics takes a fresh look at the essential concepts and methods of electrodynamics as a whole, uniting the most relevant contemporary topics under a common mathematical framework. It contains clear explanations of high-level concepts as well as the mutual relationships between the essential ideas of electromagnetic theory. Starting with the fundamentals of electrodynamics, it methodically covers a wide spectrum of research and applications that stem from electromagnetic phenomena, before concluding with more advanced topics such as quantum mechanics. * Includes…mehr
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Foundations of Applied Electrodynamics takes a fresh look at the essential concepts and methods of electrodynamics as a whole, uniting the most relevant contemporary topics under a common mathematical framework. It contains clear explanations of high-level concepts as well as the mutual relationships between the essential ideas of electromagnetic theory. Starting with the fundamentals of electrodynamics, it methodically covers a wide spectrum of research and applications that stem from electromagnetic phenomena, before concluding with more advanced topics such as quantum mechanics. * Includes new advances and methodologies in applied electrodynamics, and provides the whole picture of the theory of electrodynamics in most active areas of engineering applications * Systematically deals with eigenvalue problems, integral equation formulations and transient phenomena in various areas of applied electrodynamics * Introduces the complete theory of spherical vector wave functions, and presents the upper bounds of the product of gain and bandwidth for an arbitrary antenna * Presents the field approach to multiple antenna system, which provides a theoretical tool for the prediction of channel models of MIMO, and is also the basis of wireless power transmission system * One of the first books on electromagnetics that contains the general theory of relativity, which is needed in the design of mobile systems such as global positioning system (GPS) By summarising both engineering and theoretical electromagnetism in one volume, this book is an essential reference for practicing engineers, as well as a guide for those who wish to advance their analytical techniques for studying applied electrodynamics.
Produktdetails
- Produktdetails
- Verlag: John Wiley & Sons
- Seitenzahl: 522
- Erscheinungstermin: 22. März 2010
- Englisch
- ISBN-13: 9780470661352
- Artikelnr.: 37298230
- Verlag: John Wiley & Sons
- Seitenzahl: 522
- Erscheinungstermin: 22. März 2010
- Englisch
- ISBN-13: 9780470661352
- Artikelnr.: 37298230
Dr Geyi Wen, Consultant, Waterloo, Canada Dr Wen is the former Director of Advanced Technology, Research In Motion Ltd., Canada. His current research interests include antennas and propagation, microwave theory and techniques, and applied mathematics and physics. He has authored two books and more than one hundred publications, and has received a number of awards. As well as being the inventor of a number of patents, he is listed in Who's Who in the World and Who's Who in America.
Preface. 1 Maxwell Equations. 1.1 Experimental Laws. 1.2 Maxwell Equations, Constitutive Relation, and Dispersion. 1.3 Theorems for Electromagnetic Fields. 1.4 Wavepackets. 2 Solutions of Maxwell Equations. 2.1 Linear Space and Linear Operator. 2.2 Classification of Partial Differential Equations. 2.3 Modern Theory of Partial Differential Equations. 2.4 Method of Separation of Variables. 2.5 Method of Green's Function. 2.6 Potential Theory. 2.7 Variational Principles. 3 Eigenvalue Problems. 3.1 Introduction to Linear Operator Theory. 3.2 Eigenvalue Problems for Symmetric Operators. 3.3 Interior Electromagnetic Problems. 3.4 Exterior Electromagnetic Problems. 3.5 Eigenfunctions of Curl Operator. 4 Antenna Theory. 4.1 Antenna Parameters. 4.2 Properties of Far Fields. 4.3 Spherical Vector Wavefunctions. 4.4 Foster Theorems and Relationship Between Quality Factor and Bandwidth. 4.5 Minimum Possible Antenna Quality Factor. 4.6 Maximum Possible Product of Gain and Bandwidth. 4.7 Evaluation of Antenna Quality Factor. 5 Integral Equation Formulations. 5.1 Integral Equations. 5.2 TEM Transmission Lines. 5.3 Waveguide Eigenvalue Problems. 5.4 Metal Cavity Resonators. 5.5 Scattering Problems. 5.6 Multiple Metal Antenna System. 5.7 Numerical Methods. 6 Network Formulations. 6.1 Transmission Line Theory. 6.2 Scattering Parameters for General Circuits. 6.3 Waveguide Junctions. 6.4 Multiple Antenna System. 6.5 Power Transmission Between Antennas. 6.6 Network Parameters in a Scattering Environment. 6.7 RLC Equivalent Circuits. 7 Fields in Inhomogeneous Media. 7.1 Foundations of Spectral Analysis. 7.2 Plane Waves in Inhomogeneous Media. 7.3 Inhomogeneous Metal Waveguides. 7.4 Optical Fibers. 7.5 Inhomogeneous Cavity Resonator. 8 Time-domain Theory. 8.1 Time-domain Theory of Metal Waveguides. 8.2 Time-domain Theory of Metal Cavity Resonators. 8.3 Spherical Wave Expansions in Time-domain. 8.4 Radiation and Scattering in Time-domain. 9 Relativity. 9.1 Tensor Algebra on Linear Spaces. 9.2 Einstein's Postulates for Special Relativity. 9.3 The Lorentz Transformation. 9.4 Relativistic Mechanics in Inertial Reference Frame. 9.5 Electrodynamics in Inertial Reference Frame. 9.6 General Theory of Relativity. 10 Quantization of Electromagnetic Fields. 10.1 Fundamentals of Quantum Mechanics. 10.2 Quantization of Free Electromagnetic Fields. 10.3 Quantum Statistics. 10.4 Interaction of Electromagnetic Fields with the Small Particle System. 10.5 Relativistic Quantum Mechanics. Appendix A: Set Theory. A.1 Basic Concepts. A.2 Set Operations. A.3 Set Algebra. Appendix B: Vector Analysis. B.1 Formulas from Vector Analysis. B.2 Vector Analysis in Curvilinear Coordinate Systems. Appendix C: Special Functions. C.1 Bessel Functions. C.2 Spherical Bessel Functions. C.3 Legendre Functions and Associated Legendre Functions. Appendix D: SI Unit System. Bibliography. Index.
Chapter 1 Maxwell Equations 1.1 Experimental laws 1.2 Maxwell equations,
constitutive relation, and dispersion 1.3 Theorems for electromagnetic
fields 1.4 Wavepackets Chapter 2 Solutions of Maxwell Equations 2.1 Linear
space and linear operator 2.2 Classification of partial differential
equations 2.3 Modern theory of partial differential equations 2.4 Method of
separation of variables 2.5 Method of Green's function 2.6 Potential theory
2.7 Variational principles Chapter 3 Eigenvalue Problems 3.1 Introduction
to linear operator theory 3.2 Eigenvalue problems for symmetric operators
3.3 Interior electromagnetic problems 3.4 Exterior electromagnetic problems
3.5 Eigenfunctions of curl operator Chapter 4 Antenna Theory 4.1 Antenna
Parameters 4.2 Properties of far field patterns 4.3 Spherical vector
wavefunctions 4.4 Foster theorems and relationship between quality factor
and bandwidth 4.5 Minimum possible antenna quality factor 4.6 Maximum
possible product of gain and bandwidth 4.7 Evaluation of antenna quality
factor Chapter 5 Integral Equation Formulations 5.1 Integral equations 5.2
TEM transmission lines 5.3 Waveguide eigenvalue problems 5.4 Metal cavity
resonators 5.5 Scattering problems 5.6 Multiple metal antenna system 5.7
Numerical methods Chapter 6 Network Formulations 6.1 Transmission line
theory 6.2 Scattering parameters for general circuits 6.3 Waveguide
junctions 6.4 Multiple antenna system 6.5 Power transmission between
antennas 6.6 Network parameters in a scattering environment 6.7 RLC
equivalent circuits Chapter 7 Fields in Inhomogeneous Media 7.1 Foundations
of spectrum analysis 7.2 Plane waves in inhomogeneous media 7.3
Inhomogeneous metal waveguides 7.4 Optical fibers 7.5 Inhomogeneous cavity
resonator Chapter 8 Time-domain Theory 8.1 Time-domain theory of metal
waveguides 8.2 Time-domain theory of metal cavity resonators 8.3 Spherical
wave expansions in time domain 8.4 Radiation and scattering in time domain
Chapter 9 Relativity 9.1 Tensor algebra on linear spaces 9.2 Einstein's
postulates for special relativity 9.3 Lorentz transformation 9.4
Relativistic mechanics in inertial reference frame 9.5 Electrodynamics in
inertial reference frame 9.6 General theory of relativity Chapter 10
Quantization of Electromagnetic Fields 10.1 Fundamentals of quantum
mechanics 10.2 Quantization of free electromagnetic fields 10.3 Quantum
statistics 10.4 Interaction of fields with small particle system 10.5
Relativistic quantum mechanics Appendix A. Set theory A.1 Basic concepts
A.2 Set operations A.3 Set algebra Appendix B. Vector analysis B.1 Formulas
from vector analysis B.2 Vector analysis in curvilinear coordinate systems
Appendix C. Special functions C.1 Bessel functions C.2 Spherical Bessel
functions C.3 Legendre functions and associated Legendre functions Appendix
D. SI Unit System Bibliography Subject index
constitutive relation, and dispersion 1.3 Theorems for electromagnetic
fields 1.4 Wavepackets Chapter 2 Solutions of Maxwell Equations 2.1 Linear
space and linear operator 2.2 Classification of partial differential
equations 2.3 Modern theory of partial differential equations 2.4 Method of
separation of variables 2.5 Method of Green's function 2.6 Potential theory
2.7 Variational principles Chapter 3 Eigenvalue Problems 3.1 Introduction
to linear operator theory 3.2 Eigenvalue problems for symmetric operators
3.3 Interior electromagnetic problems 3.4 Exterior electromagnetic problems
3.5 Eigenfunctions of curl operator Chapter 4 Antenna Theory 4.1 Antenna
Parameters 4.2 Properties of far field patterns 4.3 Spherical vector
wavefunctions 4.4 Foster theorems and relationship between quality factor
and bandwidth 4.5 Minimum possible antenna quality factor 4.6 Maximum
possible product of gain and bandwidth 4.7 Evaluation of antenna quality
factor Chapter 5 Integral Equation Formulations 5.1 Integral equations 5.2
TEM transmission lines 5.3 Waveguide eigenvalue problems 5.4 Metal cavity
resonators 5.5 Scattering problems 5.6 Multiple metal antenna system 5.7
Numerical methods Chapter 6 Network Formulations 6.1 Transmission line
theory 6.2 Scattering parameters for general circuits 6.3 Waveguide
junctions 6.4 Multiple antenna system 6.5 Power transmission between
antennas 6.6 Network parameters in a scattering environment 6.7 RLC
equivalent circuits Chapter 7 Fields in Inhomogeneous Media 7.1 Foundations
of spectrum analysis 7.2 Plane waves in inhomogeneous media 7.3
Inhomogeneous metal waveguides 7.4 Optical fibers 7.5 Inhomogeneous cavity
resonator Chapter 8 Time-domain Theory 8.1 Time-domain theory of metal
waveguides 8.2 Time-domain theory of metal cavity resonators 8.3 Spherical
wave expansions in time domain 8.4 Radiation and scattering in time domain
Chapter 9 Relativity 9.1 Tensor algebra on linear spaces 9.2 Einstein's
postulates for special relativity 9.3 Lorentz transformation 9.4
Relativistic mechanics in inertial reference frame 9.5 Electrodynamics in
inertial reference frame 9.6 General theory of relativity Chapter 10
Quantization of Electromagnetic Fields 10.1 Fundamentals of quantum
mechanics 10.2 Quantization of free electromagnetic fields 10.3 Quantum
statistics 10.4 Interaction of fields with small particle system 10.5
Relativistic quantum mechanics Appendix A. Set theory A.1 Basic concepts
A.2 Set operations A.3 Set algebra Appendix B. Vector analysis B.1 Formulas
from vector analysis B.2 Vector analysis in curvilinear coordinate systems
Appendix C. Special functions C.1 Bessel functions C.2 Spherical Bessel
functions C.3 Legendre functions and associated Legendre functions Appendix
D. SI Unit System Bibliography Subject index
Preface. 1 Maxwell Equations. 1.1 Experimental Laws. 1.2 Maxwell Equations, Constitutive Relation, and Dispersion. 1.3 Theorems for Electromagnetic Fields. 1.4 Wavepackets. 2 Solutions of Maxwell Equations. 2.1 Linear Space and Linear Operator. 2.2 Classification of Partial Differential Equations. 2.3 Modern Theory of Partial Differential Equations. 2.4 Method of Separation of Variables. 2.5 Method of Green's Function. 2.6 Potential Theory. 2.7 Variational Principles. 3 Eigenvalue Problems. 3.1 Introduction to Linear Operator Theory. 3.2 Eigenvalue Problems for Symmetric Operators. 3.3 Interior Electromagnetic Problems. 3.4 Exterior Electromagnetic Problems. 3.5 Eigenfunctions of Curl Operator. 4 Antenna Theory. 4.1 Antenna Parameters. 4.2 Properties of Far Fields. 4.3 Spherical Vector Wavefunctions. 4.4 Foster Theorems and Relationship Between Quality Factor and Bandwidth. 4.5 Minimum Possible Antenna Quality Factor. 4.6 Maximum Possible Product of Gain and Bandwidth. 4.7 Evaluation of Antenna Quality Factor. 5 Integral Equation Formulations. 5.1 Integral Equations. 5.2 TEM Transmission Lines. 5.3 Waveguide Eigenvalue Problems. 5.4 Metal Cavity Resonators. 5.5 Scattering Problems. 5.6 Multiple Metal Antenna System. 5.7 Numerical Methods. 6 Network Formulations. 6.1 Transmission Line Theory. 6.2 Scattering Parameters for General Circuits. 6.3 Waveguide Junctions. 6.4 Multiple Antenna System. 6.5 Power Transmission Between Antennas. 6.6 Network Parameters in a Scattering Environment. 6.7 RLC Equivalent Circuits. 7 Fields in Inhomogeneous Media. 7.1 Foundations of Spectral Analysis. 7.2 Plane Waves in Inhomogeneous Media. 7.3 Inhomogeneous Metal Waveguides. 7.4 Optical Fibers. 7.5 Inhomogeneous Cavity Resonator. 8 Time-domain Theory. 8.1 Time-domain Theory of Metal Waveguides. 8.2 Time-domain Theory of Metal Cavity Resonators. 8.3 Spherical Wave Expansions in Time-domain. 8.4 Radiation and Scattering in Time-domain. 9 Relativity. 9.1 Tensor Algebra on Linear Spaces. 9.2 Einstein's Postulates for Special Relativity. 9.3 The Lorentz Transformation. 9.4 Relativistic Mechanics in Inertial Reference Frame. 9.5 Electrodynamics in Inertial Reference Frame. 9.6 General Theory of Relativity. 10 Quantization of Electromagnetic Fields. 10.1 Fundamentals of Quantum Mechanics. 10.2 Quantization of Free Electromagnetic Fields. 10.3 Quantum Statistics. 10.4 Interaction of Electromagnetic Fields with the Small Particle System. 10.5 Relativistic Quantum Mechanics. Appendix A: Set Theory. A.1 Basic Concepts. A.2 Set Operations. A.3 Set Algebra. Appendix B: Vector Analysis. B.1 Formulas from Vector Analysis. B.2 Vector Analysis in Curvilinear Coordinate Systems. Appendix C: Special Functions. C.1 Bessel Functions. C.2 Spherical Bessel Functions. C.3 Legendre Functions and Associated Legendre Functions. Appendix D: SI Unit System. Bibliography. Index.
Chapter 1 Maxwell Equations 1.1 Experimental laws 1.2 Maxwell equations,
constitutive relation, and dispersion 1.3 Theorems for electromagnetic
fields 1.4 Wavepackets Chapter 2 Solutions of Maxwell Equations 2.1 Linear
space and linear operator 2.2 Classification of partial differential
equations 2.3 Modern theory of partial differential equations 2.4 Method of
separation of variables 2.5 Method of Green's function 2.6 Potential theory
2.7 Variational principles Chapter 3 Eigenvalue Problems 3.1 Introduction
to linear operator theory 3.2 Eigenvalue problems for symmetric operators
3.3 Interior electromagnetic problems 3.4 Exterior electromagnetic problems
3.5 Eigenfunctions of curl operator Chapter 4 Antenna Theory 4.1 Antenna
Parameters 4.2 Properties of far field patterns 4.3 Spherical vector
wavefunctions 4.4 Foster theorems and relationship between quality factor
and bandwidth 4.5 Minimum possible antenna quality factor 4.6 Maximum
possible product of gain and bandwidth 4.7 Evaluation of antenna quality
factor Chapter 5 Integral Equation Formulations 5.1 Integral equations 5.2
TEM transmission lines 5.3 Waveguide eigenvalue problems 5.4 Metal cavity
resonators 5.5 Scattering problems 5.6 Multiple metal antenna system 5.7
Numerical methods Chapter 6 Network Formulations 6.1 Transmission line
theory 6.2 Scattering parameters for general circuits 6.3 Waveguide
junctions 6.4 Multiple antenna system 6.5 Power transmission between
antennas 6.6 Network parameters in a scattering environment 6.7 RLC
equivalent circuits Chapter 7 Fields in Inhomogeneous Media 7.1 Foundations
of spectrum analysis 7.2 Plane waves in inhomogeneous media 7.3
Inhomogeneous metal waveguides 7.4 Optical fibers 7.5 Inhomogeneous cavity
resonator Chapter 8 Time-domain Theory 8.1 Time-domain theory of metal
waveguides 8.2 Time-domain theory of metal cavity resonators 8.3 Spherical
wave expansions in time domain 8.4 Radiation and scattering in time domain
Chapter 9 Relativity 9.1 Tensor algebra on linear spaces 9.2 Einstein's
postulates for special relativity 9.3 Lorentz transformation 9.4
Relativistic mechanics in inertial reference frame 9.5 Electrodynamics in
inertial reference frame 9.6 General theory of relativity Chapter 10
Quantization of Electromagnetic Fields 10.1 Fundamentals of quantum
mechanics 10.2 Quantization of free electromagnetic fields 10.3 Quantum
statistics 10.4 Interaction of fields with small particle system 10.5
Relativistic quantum mechanics Appendix A. Set theory A.1 Basic concepts
A.2 Set operations A.3 Set algebra Appendix B. Vector analysis B.1 Formulas
from vector analysis B.2 Vector analysis in curvilinear coordinate systems
Appendix C. Special functions C.1 Bessel functions C.2 Spherical Bessel
functions C.3 Legendre functions and associated Legendre functions Appendix
D. SI Unit System Bibliography Subject index
constitutive relation, and dispersion 1.3 Theorems for electromagnetic
fields 1.4 Wavepackets Chapter 2 Solutions of Maxwell Equations 2.1 Linear
space and linear operator 2.2 Classification of partial differential
equations 2.3 Modern theory of partial differential equations 2.4 Method of
separation of variables 2.5 Method of Green's function 2.6 Potential theory
2.7 Variational principles Chapter 3 Eigenvalue Problems 3.1 Introduction
to linear operator theory 3.2 Eigenvalue problems for symmetric operators
3.3 Interior electromagnetic problems 3.4 Exterior electromagnetic problems
3.5 Eigenfunctions of curl operator Chapter 4 Antenna Theory 4.1 Antenna
Parameters 4.2 Properties of far field patterns 4.3 Spherical vector
wavefunctions 4.4 Foster theorems and relationship between quality factor
and bandwidth 4.5 Minimum possible antenna quality factor 4.6 Maximum
possible product of gain and bandwidth 4.7 Evaluation of antenna quality
factor Chapter 5 Integral Equation Formulations 5.1 Integral equations 5.2
TEM transmission lines 5.3 Waveguide eigenvalue problems 5.4 Metal cavity
resonators 5.5 Scattering problems 5.6 Multiple metal antenna system 5.7
Numerical methods Chapter 6 Network Formulations 6.1 Transmission line
theory 6.2 Scattering parameters for general circuits 6.3 Waveguide
junctions 6.4 Multiple antenna system 6.5 Power transmission between
antennas 6.6 Network parameters in a scattering environment 6.7 RLC
equivalent circuits Chapter 7 Fields in Inhomogeneous Media 7.1 Foundations
of spectrum analysis 7.2 Plane waves in inhomogeneous media 7.3
Inhomogeneous metal waveguides 7.4 Optical fibers 7.5 Inhomogeneous cavity
resonator Chapter 8 Time-domain Theory 8.1 Time-domain theory of metal
waveguides 8.2 Time-domain theory of metal cavity resonators 8.3 Spherical
wave expansions in time domain 8.4 Radiation and scattering in time domain
Chapter 9 Relativity 9.1 Tensor algebra on linear spaces 9.2 Einstein's
postulates for special relativity 9.3 Lorentz transformation 9.4
Relativistic mechanics in inertial reference frame 9.5 Electrodynamics in
inertial reference frame 9.6 General theory of relativity Chapter 10
Quantization of Electromagnetic Fields 10.1 Fundamentals of quantum
mechanics 10.2 Quantization of free electromagnetic fields 10.3 Quantum
statistics 10.4 Interaction of fields with small particle system 10.5
Relativistic quantum mechanics Appendix A. Set theory A.1 Basic concepts
A.2 Set operations A.3 Set algebra Appendix B. Vector analysis B.1 Formulas
from vector analysis B.2 Vector analysis in curvilinear coordinate systems
Appendix C. Special functions C.1 Bessel functions C.2 Spherical Bessel
functions C.3 Legendre functions and associated Legendre functions Appendix
D. SI Unit System Bibliography Subject index