Branislav M. Notaros

Conceptual Electromagnetics (eBook, ePUB)

• Format: ePub

Produktbeschreibung

This is a textbook on electromagnetic fields and waves completely based on conceptual understanding of electromagnetics. The text provides operational knowledge and firm grasp of electromagnetic fundamentals aimed toward practical engineering applications by combining fundamental theory and a unique and comprehensive collection of as many as 888 conceptual questions and problems in electromagnetics. Conceptual questions are designed to strongly enforce and enhance both the theoretical concepts and understanding and problem-solving techniques and skills in electromagnetics.

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Produktdetails

• Verlag: Taylor & Francis
• Seitenzahl: 586
• Erscheinungstermin: 6. Juli 2017
• Englisch
• ISBN-13: 9781498770699
• Artikelnr.: 54129667

Autorenporträt

Branislav M. NotaroS is a professor in the Department of Electrical and Computer Engineering at Colorado State University, where he also is director of the Electromagnetics Laboratory. He received a Ph.D. in electrical engineering from the University of Belgrade,Yugoslavia, in 1995. His research publications in computational and applied electromagnetics include more than 150 journal andconference papers. He is the author of textbooks Electromagnetics (2010) and MATLAB-Based Electromagnetics (2013), both with Pearson Prentice Hall. Prof. NotaroS served as general chair of FEM2012, Colorado, USA, and as guest editor of the "Special Issue on Finite Elements for Microwave Engineering," in Electromagnetics, 2014. He was the recipient of the 1999 Institution of Electrical Engineers (IEE) Marconi Premium, 2005 Institute of Electrical and Electronics Engineers (IEEE) MTT-S Microwave Prize, 2005 UMass Dartmouth Scholar of the Year Award, 2012 Colorado State University System Board of Governors Excellence in Undergraduate Teaching Award, 2012 IEEE Region 5 Outstanding Engineering Educator Award, 2014 Carnegie Foundation for the Advancement of aching Colorado Professor of the Year Award, 2015 American Society for Engineering Education ECE Distinguished Educator Award, 2015 IEEE Undergraduate Teaching Award, and many other research and teaching awards.

Inhaltsangabe

1 Electrostatic Field in Free Space. 1.1 Coulomb's Law. 1.2 Electric Field
Intensity Vector Due to Given Charge Distributions. 1.3 Electric Scalar
Potential. 1.4 Differential Relationship Between the Field and Potential in
Electrostatics, Gradient. 1.5 Gauss' Law in Integral Form. 1.6 Differential
Form of Gauss' Law, Divergence. 1.7 Conductors in the Electrostatic Field.
1.8 Electrostatic Shielding 1.9 Charge Distribution on Metallic Bodies of
Arbitrary Shapes. 1.10 Image Theory..2 Electrostatic Field in Dielectrics.
2.1 Polarization of Dielectrics. 2.2 Generalized Gauss' Law and
Permittivity.2.3 Dielectric-ielectric Boundary Conditions. 2.4 Analysis of
Capacitors with Homogeneous Dielectrics.2.5 Analysis of Capacitors with
Inhomogeneous Dielectrics. 2.6 Energy of an Electrostatic System.2.7
Dielectric Breakdown in Electrostatic Systems. 3 Steady Electric Currents.
3.1 Continuity Equation, Conductivity, and Ohm's and Joule's Laws in
Local.Form. 3.2 Resistance, Conductance, and Ohm's Law. 3.3 Boundary
Conditions for Steady Currents. 3.4 Duality Relationships in the Steady
Current Field. 3.5 Lossy Transmission Lines with Steady Currents. 4
Magnetostatic Field in Free Space. 4.1 Magnetic Force and Magnetic Flux
Density Vector. 4.2 Biot-Savart Law. 4.3 Amp`ere's Law in Integral Form.
4.4 Differential Form of Amp`ere's Law, Curl. 4.5 Law of Conservation of
Magnetic Flux. 4.6 Magnetic Vector Potential. 5 Magnetostatic Field in
Material Media 5.1 Magnetization Current. 5.2 Generalized Amp`ere's Law and
Permeability. 5.3 Boundary Conditions for the Magnetic Field. 5.4 Image
Theory for the Magnetic Field. 5.5 Magnetization Curves and Hysteresis. 5.6
Magnetic Circuits. 5.7 Magnetic Energy. 6 Time-Varying Electromagnetic
Field. 6.1 Induced Electric Field Intensity Vector. 6.2 Faraday's Law of
Electromagnetic Induction. 6.3 Electromagnetic Induction Due to Motion and
Total Induction. 6.4 Self-Inductance. 6.5 Mutual Inductance. 6.6
Displacement Current. 6.7 Maxwell's Equations for the High-Frequency
Electromagnetic Field. 6.8 Boundary Conditions for the High-Frequency
Electromagnetic Field. 6.9 Time-Harmonic Electromagnetics. 6.10 Complex
Representatives of Time-Harmonic Field and Circuit Quantities. 6.11 Lorenz
Electromagnetic Potentials. 6.12 Instantaneous and Complex Poynting Vector,
Poynting's Theorem. 7 Uniform Plane Electromagnetic Waves. 7.1 Wave
Equations. 7.2 Time-Domain Analysis of Uniform Plane Waves. 7.3
Time-Harmonic Uniform Plane Waves and Complex-Domain Analysis. 7.4
Arbitrarily Directed Uniform Plane Waves. 7.5 Theory of Time-Harmonic Waves
in Lossy Media. 7.6 Good Dielectrics and Good Conductors. 7.7 Skin Effect.
7.8 Wave Propagation in Plasmas. 7.9 Dispersion and Group Velocity. 7.10
Polarization of Electromagnetic Waves. 8 Reflection and Transmission of
Plane Waves. 8.1 Normal Incidence on a Perfectly Conducting Plane. 8.2
Normal Incidence on a Penetrable Planar Interface. 8.3 Oblique Incidence on
a Perfect Conductor. 8.4 Oblique Incidence on a Dielectric Boundary. 9
Field Analysis of Transmission Lines. 9.1 Field Analysis of Lossless
Transmission Lines. 9.2 Transmission Lines With Small Losses. 9.3
Evaluation of Primary and Secondary Circuit Parameters of Transmission.
Lines. 9.4 Transmission Lines With Inhomogeneous Dielectrics. 10 Circuit
Analysis of Transmission Lines. 10.1 Telegrapher's Equations and Their
Solution. 10.2 Reflection Coefficient for Transmission Lines. 10.3
Transmission-Line Impedance. 10.4 Short-Circuited, Open-Circuited, and
Matched Transmission Lines. 10.5 The Smith Chart. 10.6 Transient Analysis
of Transmission Lines with Step Excitations. 10.7 Analysis of Transmission.