Chapter 1 Vector Algebra and Coordinate System 1.1 Vector and Vector Field 1.2 Vector Algebra 1.2.1 Vector Addition and Subtraction 1.2.2 Vector Scaling 1.2.

3 Scalar or Dot Product 1.2.4 Vector or Cross Product 1.2.5 Scalar and Vector Triple Products 1.3 Orthogonal Coordinate Systems 1.3.1 Cartesian Coordinate System 1.

3.2 Cylindrical Coordinate System 1.3.3 Spherical Coordinate System 1.4 Coordinate Transformation 1.4.1 Cartesian-Cartesian Transformation 1.4.

2 Cylindrical-Cartesian Transformation 1.4.3 Spherical-Cartesian Transformation Chapter 2 Vector Calculus 2.1 Line and Surface Integrals 2.1.1 Curves 2.1.2 Line Integral 2.

1.3 Surface Integral 2.2 Directional Derivative and Gradient 2.3 Flux and Flux Density 2.4 Divergence and Divergence Theorem 2.4.1 Divergence of the Flux Density 2.4.

2 Divergence Theorem 2.5 Curl and Stokes''s Theorem 2.5.1 Curl of the Vector Field 2.5.2 Stokes''s Theorem 2.6 Dual Operation of Ñ 2.7 Helmholtz''s Theorem Chapter 3 Electrostatics 3.

1 Coulomb''s Law 3.2 Electric Field Intensity 3.2.1 Electric Field due to Multiple Charges 3.2.2 Electric Field due to Continuous Charge Distribution 3.3 Electric Flux Density and Gauss''s Law 3.3.

1 Electric Flux Density 3.3.2 Gauss''s Law 3.4 Electric Potential 3.4.1 Work Done in Moving Charges 3.4.2 Electric Potential and Potential Difference 3.

4.3 Conservative Field 3.4.4 E as the Negative Gradient of V 3.5 Dielectric in Static Electric Field 3.5.1 Electric Polarization 3.5.

2 Dielectric Constant 3.5.3 Boundary Conditions at the Dielectric Interface 3.6 Perfect Conductor in Static Electric Field 3.7 Electrostatic Potential Energy 3.8 Electrostatic Boundary-Value Problems 3.8.1 Poisson''s and Laplace''s Equations 3.

8.2 Uniqueness Theorem 3.8.3 Examples of Boundary-Value Problems 3.8.4 The Method of Images 3.8.4.

1 Line Images 3.9 Capacitor and Capacitance 3.9.1 Parallel-Plate Capacitor 3.9.1.1 The Principle of Virtual Displacement 3.9.

2 Examples of Capacitors Chapter 4 Steady Electric Current 4.1 Convection Current 4.2 Conduction Current and Ohm''s Law 4.3 The Equation of Continuity 4.3.1 Relaxation Time 4.4 Steady Currents at the Interface 4.5 The Charge Relaxation Method 4.

6 Resistance 4.7 Power Dissipation and Joule''s Law 4.8 Analogy between D and J Chapter 5 Magnetostatics 5.1 Lorentz Force Equation 5.2 The Biot-Savart Law 5.3 Ampere''s Circuital Law 5.4 Magnetic Flux Density 5.5 Vector Magnetic Potential 5.

5.1 Ampere''s Circuital Law from the Biot-Savart Law 5.6 Magnetic Dipole 5.7 Magnetic Materials 5.7.1 Magnetization and Magnetization Current 5.7.2 Permeability 5.

7.3 Hysteresis of Ferromagnetic Materials 5.7.4 Magnetic Boundary Conditions 5.8 Inductance and Inductor 5.9 Magnetic Energy 5.9.1 Magnetic Energy in Inductor 5.

9.2 Magnetic Energy in Terms of Magnetic Field 5.10 Magnetic Force and Torque 5.10.1 Magnetic Force on Current-Carrying Conductor 5.10.2 Magnetic Force and Virtual Work 5.10.

3 Magnetic Torque Chapter 6 Time-Varying Fields and Maxwell''s Equations 6.1 Faraday''s Law 6.1.1 Transformer emf 6.1.1.1 Ideal Transformer 6.1.

2 Motional emf 6.1.3 Loop Moving in Time-Varying Magnetic Field 6.2 Displacement Current Density 6.3 Maxwell''s Equations 6.3.1 Maxwell''s Equations in Integral Form 6.3.

2 Electromagnetic Boundary Conditions 6.4 Retarded Potential Chapter 7 Wave Motion 7.1 One-Dimensional Wave 7.1.1 Harmonic Wave 7.1.2 Harmonic Wave in Complex Form 7.1.

3 Harmonic Wave in Phasor Form 7.2 Plane Wave in Three-Dimensional Space 7.3 Electromagnetic Plane Wave 7.3.1 Transverse Electromagnetic Wave Chapter 8 Time-Harmonic Electromagnetic Wave 8.1 Phasor 8.1.1 Maxwell''s Equations in Phasor Form 8.

2 Wave in Homogeneous Medium 8.2.1 Uniform Plane Wave in Lossless Dielectric 8.2.2 Flow of Wave Power and Poynting Vector 8.2.3 Wave Polarization 8.2.

3.1 Linear Polarization 8.2.3.2 Circular Polarization 8.2.3.3 Elliptical Polarization 8.

2.4 Wave Propagation in Lossy Media 8.2.4.1 Plane Wave in Dielectric with Damping Loss 8.2.4.2 Plane Wave in Dielectric with Low Conductivity 8.

2.4.3 Plane Wave in Good Conductor 8.3 Plane Waves at the Interface 8.3.1 Normal Incidence of Plane Wave 8.3.1.

1 Standing-Wave Ratio 8.3.1.2 Interface Involving Perfect Conductor 8.3.2 Oblique Incidence of Plane Wave 8.3.2.

1 Perpendicular Polarization 8.3.2.2 Parallel Polarization 8.3.2.3 Brewster Angle 8.3.

3 Total Internal Reflection 8.3.4 Reflectance and Transmittance 8.4 Wave in Dispersive Media Chapter 9 Transmission Line 9.1 Transmission Line Equations 9.1.1 Transmission Line Equations in Phasor Form 9.1.

2 The Relationship Between Parameters 9.2 Transmission Line Parameters 9.2.1 Coaxial Transmission Line 9.2.2 Two-Wire Transmission Line 9.2.3 Parallel-Plate Transmission Line 9.

3 Wave Propagation on the Transmission Line 9.3.1 Lossless Transmission Line 9.3.2 Distortionless Transmission Line 9.3.3 Power Transmission and Attenuation 9.4 Finite Transmission Line 9.

4.1 Reflection Coefficient and Standing-Wave Ratio 9.4.2 Input Impedance 9.4.3 Short-Circuit and Open-Circuit Lines 9.4.3.

1 Short-Circuit Line 9.4.3.2 Open-Circuit Line 9.4.3.3 Shortening and Opening of Lossless Line 9.5 The Smith Chart 9.

5.1 Relationship Between G and 9.5.2 Relationship Between G and 9.5.3 Relationship Between G and Standing-Wave Ratio 9.5.4 Admittance on the Smith Chart 9.

5.5 Transmission Line Impedance Matching 9.5.5.1 Quarter-Wave Transformer 9.5.5.2 Single-Stub Method Chapter 10 Waveguide 10.

1 Parallel-Plate Waveguide 10.1.1 Transverse Electromagnetic (TEM) Wave 10.1.2 Transverse Electric (TE) Wave 10.1.3 Transverse Magnetic (TM) Wave 10.2 Rectangular Waveguide 10.

2.1 Transverse Magnetic (TM) Mode 10.2.1.1 Longitudinal Field Components of TM mode 10.2.1.2 Transverse Field Components of TM mode 10.

2.1.3 Orthonormal Set in TM modes 10.2.2 Transverse Electric (TE) Mode 10.2.2.1 Orthonormal Set in TE modes 10.

2.3 Power Attenuation 10.3 Rectangular Cavity Resonator 10.3.1 Resonant Frequency 10.3.2 Quality Factor of Cavity Resonator Chapter 11 Antenna 11.1 The Hertzian Dipole 11.

2 Antenna Characteristics 11.3 Linear Antenna 11.3.1 Half-Wave Dipole 11.3.2 Magnetic Dipole Antenna 11.4 Antenna Arrays 11.4.

1 Two-Element Array 11.4.2 Uniform Linear Array 11.5 Antenna in Receiving Mode 11.6 The Radar Equation.