Chapter 1 Introduction -- 1.1 Introduction -- 1.2 Emerging Technologies that Use Advance EM -- 1.3 Wireless Mobile Communication Systems -- 1.4 Modern Pedagogy in Advanced Electromagnetics -- 1.5 Design Project: Wireless Energy Harvester -- 1.6 Conclusion -- 1.7 Questions -- Chapter 2 Vector Analyses -- 2.1 Introduction -- 2.2 Vector Analysis -- 2.3 Vector Operators: Gradient, Divergence, Curl -- 2.4 Divergence Theorem -- 2.5 Stokes' Theorem -- 2.6 Two Vector Null Identities -- Chapter 3 Electromagnetism -- Section I: Historical perspective of electromagnetism -- 3.1 Introduction to Electromagnetism -- 3.2 Historical perspective of electromagnetics Theory -- 3.3 Time-varying/Dynamic electromagnetics field -- 3.4 Discussion of Advanced Electromagnetic theory -- 3.5 Problems -- Chapter 4: Electrostatics -- 4.1 Detailed Revision of Electromagnetic Fundamentals -- 4.2 Electric Field Intensity -- 4.3 Gauss' Law -- 4.4 Electrostatic Current and Ohm's Law -- 4.5 Electric Energy and Joule's Law -- 4.6 Boundary Value Problem and Electrostatic Boundary Conditions -- 4.7 Electrostatic Potential Energy -- 4.8 Summary of electrostatic theory -- 4.9 Problems -- Chapter 5: Magnetostatics -- 5.1 Magnetostatic -- 5.2 Magnetic Flux Density -- 5.3 Ampere's circuital law -- 5.4 Magnetic Vector Potential -- 5.5 Boundary Conditions of Magnetic Fields -- 5.6 Boundary Conditions for Tangential Components of H -- 5.7 Magnetic Energy and Inductance -- 5.8 Case study: Cochlear implant -- 5.9 Duality Between Electric and Magnetic Circuit Quantities -- 5.10 Summary of Chapter -- 5.11 Problems -- Chapter 6 Time Varying Electromagnetics -- 6.1 Introduction -- 6.2 The dawn of time varying electromagnetic field -- 6.3 Maxwell's current continuity equation -- 6.4 Relaxation time and conductivity of conductor -- 6.5 Displacement Current -- 6.6 Example of Displacement Current -- 6.7 Maxwell's Equations -- 6.8 Boundary Conditions in Static EM fields -- 6.9 Boundary Conditions of Time-varying EM Fields -- 6.10 Nonhomogeneous wave equation for potential functions -- 6.11 Retarded potentials -- 6.12 Homogeneous EM Wave Equations -- 6.13 Summary of Wave equations -- 6.14 Usefulness of Phasor Notation of Field Quantities -- 6.15 Electromagnetic Spectrum -- 6.16 Summary of time varying electromagnetism: -- 6.17 Chapter Summary -- 6.18 References -- Chapter 7 Uniform Plane Wave -- 7.1 Introduction to Uniform Plane Wave -- 7.2 Fundamental Concept of Wave Propagation -- 7.3 Plane Wave concept -- 7.4 One Dimensional Wave Equation Concept -- 7.5 Wave motion and wave front -- 7.6 Phase Velocity of UPW -- 7.7 Wave Impedance -- 7.8 Time Harmonic Field Wave Equations -- 7.9 Refractive Index of Medium and Dispersion -- 7.10 Time Harmonic Wave Solution -- 7.11 Polarisation of Uniform Plane Wave -- 7.12 Poynting Theorem -- 7.13 Static Poynting Theorem -- 7.14 Energy balance equation in the presence of a generator: in-flux and out-flow of Power -- 7.15 Time Harmonic Poynting Vector -- 7.16 Application: Doppler Radar -- 7.17 Summary of Chapter -- 7.18 Questions: Uniform Plane Wave Propagation -- Chapter 8 Reflection and Transmission of Uniform Plane Wave -- 8.1 Introduction -- 8.2 Electromagnetic waves analysis in the context of boundary value problems -- 8.3 Reflection and refraction at plane surface -- 8.4 Normal Incidence at Dielectric Boundary -- 8.5 Concept of Standing Waves -- 8.6 Problems -- Chapter 9 Propagation in Emerging and Advanced materials -- 9.1 Introduction -- 9.2 Applications -- 9.3 Normal Incidence on Imperfect Media -- 9.4 Applications of normal incidences on lossy dielectric boundary -- 9.5 Oblique incidence in lossy medium -- 9.6 Emerging Applications AEM in Precision Agriculture -- 9.7 Summary of chapter -- 9.8 References -- 9.9 Problems -- Chapter 10 EM Passive Guiding Devices -- 10.1 Introduction -- 10.2 Various Transmission Lines -- 10.3 Transmission line theory -- 10.4 Calculations of distributive parameters of transmission lines -- 10.5 Loaded Transmission Line -- 10.6 Smith Chart -- Chapter 11 EM testing method -- 11.1 Basic Principles -- 11.2 History of EM testing -- 11.3 Developments in Electromagnetic Induction Tests -- 11.4 Microwave Nondestructive Testing -- 11.5 Who conducted EM testing method -- 11.6 TÜV Rheinland -- 11.7 UL (Underwriters Laboratories) [3-2] -- 11.8 SGS [3-3] -- 11.9 Intertek [3-4] -- 11.10 Standard for EM testing method -- 11.11 Who writes this standard -- 11.12 International Standards -- 11.13 Testing Procedures -- 11.14 Type of standard -- 11.15 Types of EM Testing -- Chapter 12 Simulation Tools and AI -- 12.1 History of Artificial Intelligence -- 12.2 Functional of Artificial Intelligence -- 12.3 AI in electromagnetism -- 12.4 Electromagnetic Simulation and Modeling -- 12.5 Electromagnetic Interference (EMI) and Electromagnetic Compatibility (EMC) -- 12.6 Wireless communication -- Chapter 13 RF Sources and Interference -- 13.1 Introduction -- 13.2 Fundamentals of RF (Radio Frequency) Sources -- 13.3 Types of RF Sources -- 13.4 Design and Operation of RF Sources -- 13.5 Introduction to EMI/EMC (Electromagnetic Interference / Electromagnetic -- 13.6 Sources of EMI -- 13.7 Effects of EMI -- 13.8 EMC Design Principles -- 13.9 Testing and Measurement for EMI/EMC -- 13.10 Case Studies and Applications -- 13.11 Future Trends and Technologies -- 13.12 Conclusion -- Chapter 14 Deep Space Communications and Positioning -- 14.1 Introduction -- 14.2 The History of NASA's Deep Space Network -- 14.3 The Deep Space Network Functional Description -- 14.4 Advanced Techniques in Deep Space Navigation -- 14.5 Telemetry Operations in the Deep Space Network -- 14.6 Deep Space Network Capabilities and Innovations -- 14.7 Data Types and Handling in the Deep Space Network -- 14.8 The Role of the Deep Space Network in the Apollo Program -- References.