| Preface |
| The Authors |
| The Finite-Element Method / Chapter 1: |
| Historical Background / 1.1: |
| The Range of Applications / 1.2: |
| Elementary Ideas of the Finite-Element Method / 1.3: |
| Outline of Finite-Element Calculations / 1.4: |
| Elements / 1.5: |
| Applications to Waveguide Problems / 1.6: |
| Vectorial Wave Analysis by the One-Dimensional, Finite-Element Method / 1.6.1: |
| Vectorial Wave Analysis by the Two-Dimensional, Finite-Element Method / 1.6.2: |
| Treatment of Infinite Regions / 1.6.3: |
| Some Precautions for Programming / 1.7: |
| References |
| The Boundary-Element Method / Chapter 2: |
| Introduction / 2.1: |
| Limitations of the Method / 2.2: |
| Integral Representations / 2.4: |
| Two-Dimensional Problems / 2.4.1: |
| Fields Due to Source Distributions / 2.4.2: |
| General Vector-Field Problems / 2.4.3: |
| Integral Equations / 2.5: |
| Expressions with the Observation Point Taken on the Boundary / 2.5.1: |
| Fundamental Integral Equations / 2.5.2: |
| Notes on the Involvement of Resonant Solutions / 2.5.3: |
| Numerical Calculation of Integral Equations / 2.6: |
| Discretization Methods of the Boundary-Element Method / 2.6.1: |
| Discretization of Integral Equations and Derivation of Matrix Equations / 2.6.2: |
| Numerical Calculation of Elements of Coefficient Matrices / 2.6.3: |
| Some Precautions for Programming and Numerical Calculation / 2.6.4: |
| The Point-Matching Method / Chapter 3: |
| Characteristics of the Method and Range of Application / 3.1: |
| Homogeneous Dielectric Waveguides Having the Cross Section of Arbitrary Boundary / 3.3: |
| Basic Equations / 3.3.1: |
| Electromagnetic Fields of Dielectric Waveguides / 3.3.2: |
| Symmetry in the Waveguide Cross Section / 3.3.3: |
| Application of the Point-Matching Method / 3.3.4: |
| Boundary Condition Matrices / 3.3.5: |
| Designation of Propagation Modes / 3.3.6: |
| Numerical Analysis of Dielectric Waveguides Having the Cross Section of a Chipped Circle Boundary / 3.3.7: |
| Composite Dielectric Waveguides / 3.4: |
| Composite Dielectric Waveguides with Cross Sections Composed of Fan-Shaped Boundaries / 3.4.1: |
| Composite Dielectric Waveguides with Cross Sections Composed of Elliptical Boundaries / 3.4.2: |
| Coupled Dielectric Waveguides / 3.5: |
| Coupled Dielectric Waveguides Composed of Two Waveguides / 3.5.1: |
| Coupled Dielectric Waveguides Composed of Multiple Waveguides / 3.5.2: |
| Conclusion / 3.6: |
| The Mode-Matching Method / Chapter 4: |
| Formulation of Scattering by Cylindrical Obstacles / 4.1: |
| Two-Dimensional Scattering Problems / 4.2.1: |
| Scattered Far Fields / 4.2.2: |
| A Conventional Mode-Matching Method / 4.3: |
| Modal Functions and Approximate Wave Function / 4.3.1: |
| Method of Solution: E-Wave Case / 4.3.2: |
| Definition of Errors / 4.3.3: |
| Some Precautions for Numerical Computation / 4.3.4: |
| Method of Solution: H-Wave Case / 4.3.5: |
| A Smoothing Procedure / 4.4: |
| Approximation of [characters not producible] / 4.4.1: |
| Smoothing Procedure / 4.4.2: |
| Some Precautions on Using the MMM with the SP / 4.4.3: |
| Computing the Near Field / 4.4.5: |
| A Singular-Smoothing Procedure / 4.4.6: |
| E-Wave Scattering by an Edged Scatterer / 4.5.1: |
| Singular-Smoothing Procedure / 4.5.2: |
| Some Precautions on Numerical Computations / 4.5.3: |
| Numerical Examples / 4.6: |
| Scattering by a Periodic Deformed Cylinder / 4.6.1: |
| Diffraction by a Fourier Grating / 4.6.2: |
| Diffraction by an Echelette Grating / 4.6.3: |
| A General Expression and Some Examples of Modal Functions / 4.7: |
| Derivation of Equation (4.55) / Appendix 4B: |
| Iterated Kernel K[subscript p](s,t) / Appendix 4C: |
| Application of the Orthogonal Decomposition Methods / Appendix 4D: |
| The Spatial Network Method / Chapter 5: |
| Spatial Network for Three-Dimensional Maxwell's Equation / 5.1: |
| The Bergeron Method / 5.4: |
| Bergeron's Expression in the Three-Dimensional Spatial Network / 5.5: |
| Analyzed Results and Discussion / 5.6: |
| The Boundary Condition of the conductor System / 5.6.1: |
| Treatment of Dielectric Materials / 5.6.2: |
| Treatment of the Free Boundary / 5.6.3: |
| Analyzed Results / 5.6.4: |
| The Equivalent Source Method / 5.7: |
| Historical Background and Applications / 6.1: |
| Basic Theory of the Equivalent Source Method / 6.2: |
| Approximated Wave Function for the Equivalent Source Method / 6.2.1: |
| Boundary Conditions and Scattered Field / 6.2.2: |
| Error Estimation of the Scattered Field / 6.2.3: |
| Optimum Arrangement of Equivalent Sources / 6.2.4: |
| Application to Analyses of an Electromagnetic Field Scattered by Perfect-Conducting Cylinders / 6.3: |
| Numerical Examples by the Linear-Search Method / 6.3.1: |
| Numerical Examples Obtained by Nonlinear Optimization / 6.3.2: |
| Practical Analyses of the Scattered Field from Dielectric Cylinders / 6.4: |
| Approximate Wave Functions for Dielectric Region and Boundary Conditions / 6.4.1: |
| Numerical Examples of the Scattered Field from Lossless Dielectric Cylinders / 6.4.2: |
| Numerical Examples of the Scattered Field from Lossy Dielectric Cylinders / 6.4.3: |
| The Geometrical Theory of Diffraction / 6.5: |
| High-Frequency Approximation of Electromagnetic Field and Geometrical Theory of Diffraction / 7.1: |
| Geometrical Optics / 7.1.1: |
| Canonical Problems / 7.1.4: |
| Keller's GTD / 7.1.5: |
| Application of GTD and Its Defects / 7.2: |
| GTD for Diffraction from a Circular Disk / 7.2.1: |
| Diffraction from a Sphere / 7.2.2: |
| Defects of GTD / 7.2.3: |
| Improvements for Keller's GTD / 7.3: |
| Improvements to Diffraction Coefficients / 7.3.1: |
| Method of Equivalent Edge Currents / 7.3.2: |
| Modified Physical Theory of Diffraction / 7.3.3: |
| Radiation Pattern Analysis of Reflector Antennas / 7.4: |
| The Wiener-Hopf and Modified Residue Calculus Techniques / 7.5: |
| Range of Applications / 8.1: |
| Mathematical Preliminaries from the Theory of Fourier Integrals and Functions of a Complex Variable / 8.2: |
| Complex Fourier Integrals / 8.2.1: |
| Asymptotic Behavior of the Complex Fourier Integrals / 8.2.2: |
| Decomposition and Factorization of Functions / 8.2.3: |
| Saddle-Point Method / 8.2.4: |
| Wiener-Hopf Technique / 8.2.5: |
| Diffraction by a Semiinfinite Plate / 8.3: |
| Radiation Condition and Edge Condition / 8.3.1: |
| Formulation of the Problem / 8.3.2: |
| Exact Solution of the Wiener-Hopf Equation / 8.3.3: |
| Scattered-Field Representations / 8.3.4: |
| Diffraction by a Strip / 8.4: |
| Formal Solution of the Wiener-Hopf Equation / 8.4.1: |
| High-Frequency Asymptotic Solution / 8.4.3: |
| Scattered Far Field / 8.4.4: |
| Diffraction by a Thick Semiinfinite Plate / 8.5: |
| Transformed-Wave Equations / 8.5.1: |
| Simultaneous Wiener-Hopf Equations / 8.5.2: |
| Factorization of Kernel Functions / 8.5.3: |
| Formal Solutions / 8.5.4: |
| Application of the Modified Residue-Calculus Technique / 8.5.5: |
| Determination of Zeros / 8.5.6: |
| Concluding Remarks / 8.5.7: |
| Asymptotic Expansion Methods / Chapter 9: |
| Mathematical Foundations of Asymptotic Expansions / 9.1: |
| Definition of Asymptotic Expansions / 9.2.1: |
| Liouville-Green Asymptotic Expansions / 9.2.2: |
| The Airy Function / 9.2.3: |
| The Method of Matching by Gans / 9.2.4: |
| Formalism by Wentzel, Kramers, and Brillouin (WKB Method) / 9.3: |
| Higher-Order Asymptotic Solutions / 9.4: |
| Langer Transformation / 9.4.1: |
| Froman-Froman Method / 9.4.2: |
| Uniform Asymptotic Solutions / 9.4.3: |
| Eigenvalue Problems / 9.5: |
| Wentzel-Dunham Quantum Condition / 9.5.1: |
| Froman-Froman Quantum Condition / 9.5.2: |
| Maslov-Argyres Regularization / 9.5.3: |
| Uniform Asymptotic-Perturbational Method / 9.5.4: |
| Felsen Series / 9.5.5: |
| Multiple Scattering Expansions / 9.6: |
| Solutions of Coupled Equations / 9.6.1: |
| Multilayer Solutions / 9.6.2: |
| The Invariant Imbedding Approach / 9.6.3: |
| Asymptotic Expansions in an Optical Waveguide System / 9.7: |
| Significance of Expansions and the Range of Applications / 9.8: |
| References and Bibliography |
| The Beam Propagation Method / Chapter 10: |
| Features of BPM / 10.1: |
| Computing Technology / 10.1.3: |
| Construction of this Chapter / 10.1.4: |
| Basis of the Beam Propagation Method / 10.2: |
| Optical Planar Circuits / 10.2.1: |
| Principle of BPM / 10.2.2: |
| BPM in Three-Dimensional Media and Fresnel-Type Approximation / 10.3: |
| BPM Formulation of Three-Dimensional Helmholtz Equation / 10.3.1: |
| BPM Formula Based on the Fresnel Equation / 10.3.2: |
| Propagation Constants Obtained From Fresnel and Hemholz Equations / 10.3.3: |
| BPM in Anisotropic Media / 10.4: |
| Basic Variables and Assumptions / 10.4.1: |
| Formulation for BPM / 10.4.3: |
| Cases When Refractive-Index Variations in x- and y-Directions are Different / 10.4.4: |
| Examples of Calculation Results / 10.5: |
| Cases in Isotropic Media / 10.5.1: |
| Cases in Anisotropic Media / 10.5.2: |
| The Spectral Domain Method / 10.6: |
| Characteristics of the Method and the Range of Applications / 11.1: |
| Spectral Domain Method Based on the Electromagnetic-Field Expansions / 11.3: |
| Galerkin's Method of Solution / 11.4: |
| Characteristic Impedance / 11.5: |
| Immitance Method / 11.6: |
| Symmetry / 11.7: |
| Convergence / 11.7.2: |
| Other Precautions / 11.7.3: |
| Conclusions / 11.8: |
| Bibliography |
| Index |
図書