- GENERAL THEOREMS AND FORMULAS
- SCALAR GREEN FUNCTIONS
- ELECTROMAGNETIC THEORY
- DYADIC GREEN FUNCTIONS
- Maxwell’s Equations in Dyadic Form and Dyadic
- Green Functions of the Electric and Magnetic Type
- Free-Space Dyadic Green Functions
- Classification of Dyadic Green Functions
- Symmetrical Properties of Dyadic Green Functions Reciprocity Theorems
- Transmission Line Model of the Complementary Reciprocity Theorems
- Dyadic Green Functions for a Half Space Bounded by a Plane Conducting Surface
- RECTANGULAR WAVEGUIDES
- Rectangular Vector Wave Functions
- The Method of Em
- The Method of ??,
- The Method of EA
- Parallel Plate Waveguide
- Rectangular Waveguide Filled with Two Dielectrics
- Rectangular Cavity
- The Origin of the Isolated Singular Term in Ge
- CYLINDRICAL WAVEGUIDES
- Cylindrical Wave Functions with Discrete Eigenvalues
- Cylindrical Waveguide
- Cylindrical Cavity
- Coaxial Line
- CIRCULAR CYLINDER IN FREE SPACE
- Cylindrical Vector Wave Functions with Continuous Eigenvalues
- Eigenfunction Expansion of the Free-Space Dyadic Green Functions
- Conducting Cylinder, Dielectric Cylinder, and Coated Cylinder
- Asymptotic Expression
- PERFECTLY CONDUCTING ELLIPTICAL CYLINDER
- PERFECTLY CONDUCTING WEDGE AND THE HALF SHEET
- SPHERES AND PERFECTLY CONDUCTING CONES
- PLANAR STRATIFIED MEDIA
- INHOMOGENEOUS MEDIA AND MOVING MEDIUM
- Vector Wave Functions for Plane Stratified Media
- Vector Wave Functions for Spherically Stratified Media
- Inhomogeneous Spherical Lenses
- Monochromatically Oscillating Fields in a Moving Isotropic Medium
- Time-Dependent Field in a Moving Medium
- Rectangular Waveguide with a Moving Medium
- Cylindrical Waveguide with a Moving Medium
- Infinite Conducting Cylinder in a Moving Medium
- APPENDIX A MATHEMATICAL FORMULAS
- APPENDIX B VECTOR WAVE FUNCTIONS AND THEIR MUTUAL RELATIONS