Enables readers to grasp the fundamentals of applied electromagnetics through a blended pedagogical approach
Electromagnetic Applications for Guided and Propagating Waves comprehensively covers both fundamentals and advanced topics in applied electromagnetics (EM) for the professional, going above the basic static and dynamic EM field theories that are covered in most undergraduate EM textbooks. The textbook introduces complex topics with illustrations of modern technologies that use the topics, followed by a simple presentation of the basic vector analysis and Maxwell's equations, supported by many practical examples, math essays, math puzzles, and the most modern technological developments from the websites of prominent technology companies.
The textbook includes review questions at the end of each topic to enhance the students' learning experience and outcomes. It provides the links for multimedia lecture videos and directs students to relevant open sources such as YouTube videos and lecture materials from the prestigious universities of developed and developing nations. The textbook is supported by presentation slides, a solution and instructor's manual, and MATLAB program downloads.
Written by prolific teacher Dr. Karmakar, Electromagnetic Applications for Guided and Propagating Waves discusses topics including:
Fundamental theories of resonators, optical waveguides and fibers, antennas and antenna arrays, wireless systems, and electromagnetic compatibility
Electrostatic field theory and detailed derivations of electromagnetic fundamentals such as electric charges and Coulomb's law
Applications of time-varying electromagnetic fields, covering transmission lines, impedance matching techniques, and waveguides
How electromagnetics has impacted our day-to-day life and how we use it in our workplace and on social media
Historical anecdotes and evolution of EM theory from its inception to Maxwell and Hertz
Electromagnetic Applications for Guided and Propagating Waves is an essential reference for researchers, professionals, and policy and decision makers in the fields of electromagnetics, electrical engineering, wireless communications, and defense.
Sprache
Verlagsort
Verlagsgruppe
Zielgruppe
Produkt-Hinweis
Fadenheftung
Gewebe-Einband
ISBN-13
978-1-394-26282-3 (9781394262823)
Copyright in bibliographic data and cover images is held by Nielsen Book Services Limited or by the publishers or by their respective licensors: all rights reserved.
Schweitzer Klassifikation
Nemai Chandra Karmakar, PhD, is the lead researcher at the Monash Microwave, Antenna, RFID and Sensor Laboratory (MMARS) at Monash University, Australia. He received his PhD in Information Technology and Electrical Engineering from the University of Queensland, Australia, in 1999. He is a pioneer in fully printable, chipless radio-frequency identification (RFID) tags and sensors, readers, signal processing, and smart antennas.
Autor*in
Monash University, Australia
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 TUEV 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
