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Foreword; Preface; Contents; Biographies of Contributors; Part I Electromagnetic Theory; 1 Maxwell's Equations; 1.1 Differential Form; 1.2 Constitutive Relations; 1.3 Integral Form; 1.4 Boundary Relations; 1.4.1 Derivation; 1.4.2 Special Cases; 1.4.3 Other Boundary Conditions; 1.5 The Wave Equation; 1.6 Electromagnetic Potentials; 1.6.1 Lorenz's Potentials; 1.6.2 Lorenz's Gauge; 1.6.3 Gauge Transformation; 1.6.4 Coulomb's Gauge; 1.6.5 Hertz Potential; 1.7 Energy Flow; 1.7.1 Uniqueness Conditions; 1.8 Time Harmonic Fields; 1.9 Complex Poynting Theorem; 1.10 Specific Absorption Rate
1.11 Green's Function Method1.11.1 Green's Identities; 1.11.2 Inhomogeneous Scalar Helmholtz Equation; 1.11.3 Green's Function of the First Kind; 1.11.4 Green's Function of the Second Kind; 1.11.5 The Free Space Green's Function; 1.11.6 The Modified Green's Function; 1.11.7 Eigenfunction Presentation; 1.12 Inhomogeneous Vector Helmholtz Equation; 2 Radiation; 2.1 General Considerations; 2.2 Elementary Sources; 2.2.1 The Short Electric Dipole; 2.2.2 The Small Magnetic Dipole; 2.3 Wire Antennas; 2.4 Field Regions; 2.4.1 Point Sources; 2.4.2 Extended Sources
2.5 Far Field Calculation for General Antennas2.6 Antenna Parameters; 2.6.1 Antenna Patterns and Radiation Intensity; 2.6.2 Directive Gain; 2.6.3 Gain; 2.6.4 Effective Aperture; 2.6.5 Antenna Impedance; 2.6.6 Friis Transmission Formula; 3 Fundamental Theorems; 3.1 Uniqueness Theorem; 3.2 Duality; 3.3 Image Theory; 3.4 Reciprocity; 3.5 Equivalence Principles; 3.5.1 Equivalent Volumetric Currents; 3.5.2 Equivalent Surface Currents; 3.6 Babinet's Principle; 4 Wave Harmonics and Guided Waves; 4.1 Plane Waves; 4.1.1 Planar Harmonics; 4.1.2 The Sheet Current Source; 4.1.3 Wave Polarization
4.1.4 Lossless Medium4.1.5 Lossy Medium; 4.1.6 Reflection from Plane Dielectric Interfaces; 4.1.7 Propagation in Layered Media; 4.1.8 Reflection from Inhomogeneous Layers; 4.1.9 Wave Velocities; 4.2 Planar Waveguides; 4.2.1 The Parallel Plate Waveguide; 4.2.2 Grounded Dielectric Slab; 4.2.3 The Dielectric Slab Waveguide; 4.3 Hollow Waveguides; 4.3.1 Waveguide Modes; 4.3.2 Cutoff Frequency; 4.3.3 Guide Wavelength; 4.3.4 Orthogonality of Modes; 4.3.5 The Rectangular Hollow Waveguide; 4.3.6 The Corrugated Rectangular Waveguide; 4.4 Radiation from Sources in a Plane; 4.5 Cylindrical Waves
4.5.1 Line Sources4.5.2 Cylindrical Wave Transformation; 4.5.3 Addition Theorem; 4.5.4 The Circular Metallic Waveguide; 4.5.5 Circular Corrugated Horns; 4.5.6 The Coaxial Waveguide; 4.5.7 The Dielectric Rod; 4.6 Spherical Waves; 4.6.1 Spherical Wave Transformation; 4.6.2 Point Sources; 4.6.3 Addition Theorem; Part II Scattering Theory; 5 Radar; 5.1 Historical Remarks; 5.2 Operation; 5.2.1 Transmitters; 5.2.2 Radar Antennas; 5.2.3 Receivers; 5.2.4 Computer Processing; 5.2.5 Radar Displays; 5.3 Secondary-Radar System; 5.3.1 Transponder; 5.3.2 Radar Identification (IFF); 5.4 Countermeasures
1.11 Green's Function Method1.11.1 Green's Identities; 1.11.2 Inhomogeneous Scalar Helmholtz Equation; 1.11.3 Green's Function of the First Kind; 1.11.4 Green's Function of the Second Kind; 1.11.5 The Free Space Green's Function; 1.11.6 The Modified Green's Function; 1.11.7 Eigenfunction Presentation; 1.12 Inhomogeneous Vector Helmholtz Equation; 2 Radiation; 2.1 General Considerations; 2.2 Elementary Sources; 2.2.1 The Short Electric Dipole; 2.2.2 The Small Magnetic Dipole; 2.3 Wire Antennas; 2.4 Field Regions; 2.4.1 Point Sources; 2.4.2 Extended Sources
2.5 Far Field Calculation for General Antennas2.6 Antenna Parameters; 2.6.1 Antenna Patterns and Radiation Intensity; 2.6.2 Directive Gain; 2.6.3 Gain; 2.6.4 Effective Aperture; 2.6.5 Antenna Impedance; 2.6.6 Friis Transmission Formula; 3 Fundamental Theorems; 3.1 Uniqueness Theorem; 3.2 Duality; 3.3 Image Theory; 3.4 Reciprocity; 3.5 Equivalence Principles; 3.5.1 Equivalent Volumetric Currents; 3.5.2 Equivalent Surface Currents; 3.6 Babinet's Principle; 4 Wave Harmonics and Guided Waves; 4.1 Plane Waves; 4.1.1 Planar Harmonics; 4.1.2 The Sheet Current Source; 4.1.3 Wave Polarization
4.1.4 Lossless Medium4.1.5 Lossy Medium; 4.1.6 Reflection from Plane Dielectric Interfaces; 4.1.7 Propagation in Layered Media; 4.1.8 Reflection from Inhomogeneous Layers; 4.1.9 Wave Velocities; 4.2 Planar Waveguides; 4.2.1 The Parallel Plate Waveguide; 4.2.2 Grounded Dielectric Slab; 4.2.3 The Dielectric Slab Waveguide; 4.3 Hollow Waveguides; 4.3.1 Waveguide Modes; 4.3.2 Cutoff Frequency; 4.3.3 Guide Wavelength; 4.3.4 Orthogonality of Modes; 4.3.5 The Rectangular Hollow Waveguide; 4.3.6 The Corrugated Rectangular Waveguide; 4.4 Radiation from Sources in a Plane; 4.5 Cylindrical Waves
4.5.1 Line Sources4.5.2 Cylindrical Wave Transformation; 4.5.3 Addition Theorem; 4.5.4 The Circular Metallic Waveguide; 4.5.5 Circular Corrugated Horns; 4.5.6 The Coaxial Waveguide; 4.5.7 The Dielectric Rod; 4.6 Spherical Waves; 4.6.1 Spherical Wave Transformation; 4.6.2 Point Sources; 4.6.3 Addition Theorem; Part II Scattering Theory; 5 Radar; 5.1 Historical Remarks; 5.2 Operation; 5.2.1 Transmitters; 5.2.2 Radar Antennas; 5.2.3 Receivers; 5.2.4 Computer Processing; 5.2.5 Radar Displays; 5.3 Secondary-Radar System; 5.3.1 Transponder; 5.3.2 Radar Identification (IFF); 5.4 Countermeasures