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図書
図書
1. Elements of electromagnetics. 7th ed (: hardcover)
Matthew N.O. Sadiku
出版情報: New York : Oxford University Press, c2018  xviii, 6, 895 p. ; 25 cm
シリーズ名: The Oxford series in electrical and computer engineering
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目次情報: 続きを見る
Brief Table of Contents
Preface
A Note to the Student
About the Author
Math Assessment
Vector Analysis / Part 1:
Vector Algebra / 1:
Introduction / 1.1:
A Preview of the Book / 1.2:
Scalars and Vectors / 1.3:
Unit Vector / 1.4:
Vector Addition and Subtraction / 1.5:
Position and Distance Vectors / 1.6:
Vector Multiplication / 1.7:
Components of a Vector / 1.8:
Summary
Review Questions
Problems
Coordinate Systems and Transformation / 2:
Cartesian Coordinates (x, y, z) / 2.1:
Circular Cylindrical Coordinates (p, φ z) / 2.3:
Spherical Coordinates (r, θ, φ) / 2.4:
Constant-Coordinate Surfaces / 2.5:
Vector Calculus / 3:
Differential Length, Area, and Volume / 3.1:
Line, Surface, and Volume Integrals / 3.3:
Del Operator / 3.4:
Gradient of a Scalar / 3.5:
Divergence of a Vector and Divergence Theorem / 3.6:
Curl of a Vector and Stokes's Theorem / 3.7:
Laplacian of a Scalar / 3.8:
Classification of Vector Fields / 3.9:
Electrostatics / Part 2:
Electrostatic Fields / 4:
Coulomb's Law and Field Intensity / 4.1:
Electric Fields due to Continuous Charge Distributions / 4.3:
Electric Flux Density / 4.4:
Gauss's Law-Maxwell's Equation / 4.5:
Applications of Gauss's Law / 4.6:
Electric Potential / 4.7:
Relationship between E and V- Maxwell's Equation / 4.8:
An Electric Dipole and Flux Lines / 4.9:
Energy Density in Electrostatic Fields / 4.10:
Application Note-Electrostatic Discharge / 4.11:
Electric Fields in Material Space / 5:
Properties of Materials / 5.1:
Convection and Conduction Currents / 5.3:
Conductors / 5.4:
Polarization in Dielectrics / 5.5:
Dielectric Constant and Strength / 5.6:
Linear, Isotropic, and Homogeneous Dielectrics / 5.7:
Continuity Equation and Relaxation Time / 5.8:
Boundary Conditions / 5.9:
Application Note- Materials with High Dielectric Constant / 5.10:
Application Note-Graphene / 5.11:
Application Note-Piezoelectrics / 5.12:
Electrostatic Boundary-Value Problems / 6:
Poisson's and Laplace's Equations / 6.1:
Uniqueness Theorem / 6.3:
General Procedures for Solving Poisson's or Laplace's Equation / 6.4:
Resistance and Capacitance / 6.5:
Method of Images / 6.6:
Application Note-Capacitance of Microstrip Lines / 6.7:
Application Note-RF MEMS / 6.8:
Application Note-Supercapacitors / 6.9:
Magnetostatics / Part 3:
Magnetostatic Fields / 7:
Biot-Savart's Law / 7.1:
Ampère's Circuit Law-Maxwell's Equation / 7.3:
Applications of Ampère's Law / 7.4:
Magnetic Flux Density-Maxwell's Equation / 7.5:
Maxwell's Equations for Static Fields / 7.6:
Magnetic Scalar and Vector Potentials / 7.7:
Derivation of Biot-Savart's Law and Ampère's Law / 7.8:
Application Note-Lightning / 7.9:
Application Note-Polywells / 7.10:
Magnetic Forces, Materials, and Devices / 8:
Forces due to Magnetic Fields / 8.1:
Magnetic Torque and Moment / 8.3:
A Magnetic Dipole / 8.4:
Magnetization in Materials / 8.5:
Classification of Materials / 8.6:
Magnetic Boundary Conditions / 8.7:
Inductors and Inductances / 8.8:
Magnetic Energy / 8.9:
Magnetic Circuits / 8.10:
Force on Magnetic Materials / 8.11:
Application Note-Magnetic Levitation / 8.12:
Application Note-SQUIDs / 8.13:
Waves and Applications / Part 4:
Maxwell's Equations / 9:
Faraday's Law / 9.1:
Transformer and Motional Electromotive Forces / 9.3:
Displacement Current / 9.4:
Maxwell's Equations in Final Forms / 9.5:
Time-Varying Potentials / 9.6:
Time-Harmonic Fields / 9.7:
Application Note-Memristor / 9.8:
Application Note-Optical Nanocircuits / 9.9:
Application Note-Wireless Power Transfer and Qi Standard / 9.10:
Electromagnetic Wave Propagation / 10:
Waves in General / 10.1:
Wave Propagation in Lossy Dielectrics / 10.3:
Plane Waves in Lossless Dielectrics / 10.4:
Plane Waves in Free Space / 10.5:
Plane Waves in Good Conductors / 10.6:
Wave Polarization / 10.7:
Power and the Poynting Vector / 10.8:
Reflection of a Plane Wave at Normal Incidence / 10.9:
Reflection of a Plane Wave at Oblique Incidence / 10.10:
Application Note-Microwaves / 10.11:
Application Note-60 GHz Technology / 10.12:
Transmission Lines
Transmission Line Parameters / 11.1:
Transmission Line Equations / 11.3:
Input Impedance, Standing Wave Ratio, and Power / 11.4:
The Smith Chart / 11.5:
Some Applications of Transmission Lines / 11.6:
Transients on Transmission Lines / 11.7:
Application Note-Microstrip Lines and Characterization of Data Cables / 11.8:
Application Note-Metamaterials / 11.9:
Application Note-Microwave Imaging / 11.10:
Waveguides / 12:
Rectangular-Waveguides / 12.1:
Transverse Magnetic Modes / 12.3:
Transverse Electric Modes / 12.4:
Wave Propagation in the Guide / 12.5:
Power Transmission and Attenuation / 12.6:
Waveguide Current and Mode Excitation / 12.7:
Waveguide Resonators / 12.8:
Application Note-Optical Fiber / 12.9:
Application Note-Cloaking and Invisibility / 12.10:
Antennas / 13:
Hertzian Dipole / 13.1:
Half-Wave Dipole Antenna / 13.3:
Quarter-Wave Monopole Antenna / 13.4:
Small-Loop Antenna / 13.5:
Antenna Characteristics / 13.6:
Antenna Arrays / 13.7:
Effective Area and the Friis Equation / 13.8:
The Radar Equation / 13.9:
Application Note-Electromagnetic Interference and Compatibility / 13.10:
Application Note-Textile Antennas and Sensors / 13.11:
Application Note-Fractal Antennas / 13.12:
Application Note-RFID / 13.13:
Numerical Methods / 14:
Field Plotting / 14.1:
The Finite Difference Method / 14.3:
The Moment Method / 14.4:
The Finite Element Method / 14.5:
Application Note-Microstrip Lines / 14.6:
Mathematical Formulas / Appendix A:
Material Constants / Appendix B:
MATLAB / Appendix C:
The Complete Smith Chart / Appendix D:
Answers to Odd-Numbered Problems / Appendix E:
Index
Brief Table of Contents
Preface
A Note to the Student
2.

図書
図書
2. Numerical techniques in electromagnetics
Matthew N.O. Sadiku
出版情報: Boca Raton, Fla. : CRC Press, c1992  xviii, 690 p. ; 25 cm
所蔵情報: loading…
目次情報: 続きを見る
Fundamental Concepts / 1:
Introduction / 1.1:
Review of Electromagnetic Theory / 1.2:
Electrostatic Fields / 1.2.1:
Magnetostatic Fields / 1.2.2:
Time-varying Fields / 1.2.3:
Boundary Conditions / 1.2.4:
Wave Equations / 1.2.5:
Time-varying Potentials / 1.2.6:
Time-harmonic Fields / 1.2.7:
Classification of EM Problems / 1.3:
Classification of Solution Regions / 1.3.1:
Classification of Differential Equations / 1.3.2:
Classification of Boundary Conditions / 1.3.3:
Some Important Theorems / 1.4:
Superposition Principle / 1.4.1:
Uniqueness Theorem / 1.4.2:
References
Problems
Analytical Methods / 2:
Separation of Variables / 2.1:
Separation of Variables in Rectangular Coordinates / 2.3:
Laplace's Equations / 2.3.1:
Wave Equation / 2.3.2:
Separation of Variables in Cylindrical Coordinates / 2.4:
Laplace's Equation / 2.4.1:
Separation of Variables in Spherical Coordinates / 2.4.2:
Some Useful Orthogonal Functions / 2.5.1:
Series Expansion / 2.7:
Poisson's Equation in a Cube / 2.7.1:
Poisson's Equation in a Cylinder / 2.7.2:
Strip Transmission Line / 2.7.3:
Practical Applications / 2.8:
Scattering by Dielectric Sphere / 2.8.1:
Scattering Cross Sections / 2.8.2:
Attenuation Due to Raindrops / 2.9:
Concluding Remarks / 2.10:
Finite Difference Methods / 3:
Finite Difference Schemes / 3.1:
Finite Differencing of Parabolic PDEs / 3.3:
Finite Differencing of Hyperbolic PDEs / 3.4:
Finite Differencing of Elliptic PDEs / 3.5:
Band Matrix Method / 3.5.1:
Iterative Methods / 3.5.2:
Accuracy and Stability of FD Solutions / 3.6:
Practical Applications I--Guided Structures / 3.7:
Transmission Lines / 3.7.1:
Waveguides / 3.7.2:
Practical Applications II--Wave Scattering (FDTD) / 3.8:
Yee's Finite Difference Algorithm / 3.8.1:
Accuracy and Stability / 3.8.2:
Lattice Truncation Conditions / 3.8.3:
Initial Fields / 3.8.4:
Programming Aspects / 3.8.5:
Absorbing Boundary Conditions for FDTD / 3.9:
Finite Differencing for Nonrectangular Systems / 3.10:
Cylindrical Coordinates / 3.10.1:
Spherical Coordinates / 3.10.2:
Numerical Integration / 3.11:
Euler's Rule / 3.11.1:
Trapezoidal Rule / 3.11.2:
Simpson's Rule / 3.11.3:
Newton-Cotes Rules / 3.11.4:
Gaussian Rules / 3.11.5:
Multiple Integration / 3.11.6:
Variational Methods / 3.12:
Operators in Linear Spaces / 4.1:
Calculus of Variations / 4.3:
Construction of Functionals from PDEs / 4.4:
Rayleigh-Ritz Method / 4.5:
Weighted Residual Method / 4.6:
Collocation Method / 4.6.1:
Subdomain Method / 4.6.2:
Galerkin Method / 4.6.3:
Least Squares Method / 4.6.4:
Eigenvalue Problems / 4.7:
Moment Methods / 4.8:
Integral Equations / 5.1:
Classification of Integral Equations / 5.2.1:
Connection Between Differential and Integral Equations / 5.2.2:
Green's Functions / 5.3:
For Free Space / 5.3.1:
For Domain with Conducting Boundaries / 5.3.2:
Applications I--Quasi-Static Problems / 5.4:
Applications II--Scattering Problems / 5.5:
Scattering by Conducting Cylinder / 5.5.1:
Scattering by an Arbitrary Array of Parallel Wires / 5.5.2:
Applications III--Radiation Problems / 5.6:
Hallen's Integral Equation / 5.6.1:
Pocklington's Integral Equation / 5.6.2:
Expansion and Weighting Functions / 5.6.3:
Applications IV--EM Absorption in the Human Body / 5.7:
Derivation of Integral Equations / 5.7.1:
Transformation to Matrix Equation (Discretization) / 5.7.2:
Evaluation of Matrix Elements / 5.7.3:
Solution of the Matrix Equation / 5.7.4:
Finite Element Method / 5.8:
Solution of Laplace's Equation / 6.1:
Finite Element Discretization / 6.2.1:
Element Governing Equations / 6.2.2:
Assembling of All Elements / 6.2.3:
Solving the Resulting Equations / 6.2.4:
Solution of Poisson's Equation / 6.3:
Deriving Element-governing Equations / 6.3.1:
Solution of the Wave Equation / 6.3.2:
Automatic Mesh Generation I--Rectangular Domains / 6.5:
Automatic Mesh Generation II--Arbitrary Domains / 6.6:
Definition of Blocks / 6.6.1:
Subdivision of Each Block / 6.6.2:
Connection of Individual Blocks / 6.6.3:
Bandwidth Reduction / 6.7:
Higher Order Elements / 6.8:
Pascal Triangle / 6.8.1:
Local Coordinates / 6.8.2:
Shape Functions / 6.8.3:
Fundamental Matrices / 6.8.4:
Three-Dimensional Elements / 6.9:
Finite Element Methods for Exterior Problems / 6.10:
Infinite Element Method / 6.10.1:
Boundary Element Method / 6.10.2:
Absorbing Boundary Conditions / 6.10.3:
Transmission-line-matrix Method / 6.11:
Transmission-line Equations / 7.1:
Solution of Diffusion Equation / 7.3:
Solution of Wave Equations / 7.4:
Equivalence Between Network and Field Parameters / 7.4.1:
Dispersion Relation of Propagation Velocity / 7.4.2:
Scattering Matrix / 7.4.3:
Boundary Representation / 7.4.4:
Computation of Fields and Frequency Response / 7.4.5:
Output Response and Accuracy of Results / 7.4.6:
Inhomogeneous and Lossy Media in TLM / 7.5:
General Two-Dimensional Shunt Node / 7.5.1:
Representation of Lossy Boundaries / 7.5.2:
Three-Dimensional TLM Mesh / 7.6:
Series Nodes / 7.6.1:
Three-Dimensional Node / 7.6.2:
Error Sources and Correction / 7.6.3:
Truncation Error / 7.7.1:
Coarseness Error / 7.7.2:
Velocity Error / 7.7.3:
Misalignment Error / 7.7.4:
Monte Carlo Methods / 7.8:
Generation of Random Numbers and Variables / 8.1:
Evaluation of Error / 8.3:
Crude Monte Carlo Integration / 8.4:
Monte Carlo Integration with Antithetic Variates / 8.4.2:
Improper Integrals / 8.4.3:
Solution of Potential Problems / 8.5:
Fixed Random Walk / 8.5.1:
Floating Random Walk / 8.5.2:
Exodus Method / 8.5.3:
Regional Monte Carlo Methods / 8.6:
Method of Lines / 8.7:
Rectangular Coordinates / 9.1:
Solution of Wave Equation / 9.2.2:
Planar Microstrip Structures / 9.3.1:
Cylindrical Microstrip Structures / 9.3.2:
Time-Domain Solution / 9.4:
Vector Relations / 9.5:
Vector Identities / A.1:
Vector Theorems / A.2:
Orthogonal Coordinates / A.3:
Solving Electromagnetic Problems Using C++ / B:
A Brief Description of C++ / B.1:
Object-Orientation / B.3:
C++ Object-Oriented Language Features / B.4:
A Final Note / B.5:
Numerical Techniques in C++ / C:
Solution of Simultaneous Equations / D:
Elimination Methods / D.1:
Gauss's Method / D.1.1:
Cholesky's Method / D.1.2:
Jacobi's Method / D.2:
Gauss-Seidel Method / D.2.2:
Relaxation Method / D.2.3:
Gradient Methods / D.2.4:
Matrix Inversion / D.3:
Iteration (or Power) Method / D.4:
Answers to Odd-Numbered Problems / D.4.2:
Index
Fundamental Concepts / 1:
Introduction / 1.1:
Review of Electromagnetic Theory / 1.2:
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