Poljak Dragan. Advanced modeling in computational electromagnetic compatibility

John Wiley & Sons, Inc., 2007. — 520 p. — ISBN: 978-0-470-03665-5.Присутствуют страницы с 1-370, 372-374.
This text combines the fundamentals of electromagnetics with numerical modeling to tackle a broad range of current electromagnetic compatibility (EMC) problems, including problems with lightning, transmission lines, and grounding systems. It sets forth a solid foundation in the basics before advancing to specialized topics, and allows readers to develop their own EMC computational models for applications in both research and industry.Fundamental Concepts in Computational Electromagnetic Compability.
Introduction to Computational Electromagnetics and Electromagnetic Compatibility.
Historical Note on Modeling in Electromagnetics.
Electromagnetic Compatibility and Electromagnetic Interference.Fundamentals of Electromagnetic Theory.
Differential Form of Maxwell Equations.
Integral Form of Maxwell Equations.
Maxwell Equations for Moving Media.
The Continuity Equation.
Ohm’s Law.
Conservation Law in the Electromagnetic Field.
The Electromagnetic Wave Equations.
Boundary Relationships for Discontinuities in Material Properties.
The Electromagnetic Potentials.
Boundary Relationships for Potential Functions.
Potential Wave Equations.
Retarded Potentials.
General Boundary Conditions and Uniqueness Theorem.
Electric and Magnetic Walls.
The Lagrangian Form of Electromagnetic Field Laws.
Complex Phasor Notation of Time-Harmonic Electromagnetic Fields.
Transmission Line Theory.
Plane Wave Propagation.
Radiation.Introduction to Numerical Methods in Electromagnetics.
Analytical Versus Numerical Methods.
Overview of Numerical Methods: Domain, Boundary, and Source Simulation.
The Finite Difference Method.
The Finite Element Method.
The Boundary Element Method.Static Field Analysis.
Electrostatic Fields.
Magnetostatic Fields.
Modeling of Static Field Problems.Quasistatic Field Analysis.Formulation of the Quasistatic Problem.
Integral Equation Representation of the Helmholtz Equation.
Computational Example.Electromagnetic Scattering Analysis.
The Electromagnetic Wave Equations.
Complex Phasor Form of the Wave Equations.
Two-Dimensional Scattering from a Perfectly Conducting Cylinder of Arbitrary Cross-Section.
Solutio n by the Indi rect Bou ndary Element Method.
Numerical Example.Analysis of Thin Wire Antennas and Scatterers.
Wire Antennas and Scatterers: General Considerations.
Frequency Domain Thin Wire Integral Equations.
Time Domain Thin Wire Integral Equations.
Modeling in the Frequency and Time Domain: Computational Aspects.Wire Antennas and Scatterers: Frequency Domain Analysis.
Thin Wires in Free Space.
Thin Wires Above a Lossy Half-Space.Wire Antennas and Scatterers: Time Domain Analysis.
Thin Wires in Free Space.
Thin Wires in a Presence of a Two-Media Configuration.Computational Models in Electromagnetic Compability.
Transmission Lines of Finite Length: General Considerations.
Transmission Line Theory Method.
Antenna Models of the Transmission Lines.Electromagnetic Field Coupling to Overhead Lines: Frequency Domain and Time Domain Analysis.
Frequency Domain Analysis: Derivation of Generalized Telegrapher’s Equations.
Frequency Domain Computational Results.
Time Domain Analysis.
Time Domain Computational Examples.The Electromagnetic Field Coupling to Buried Cables: Frequency- and Time-Domain Analysis.
The Frequency-Domain Approach.
Time-Domain Approach.Simple Grounding Systems.
Vertical Grounding Electrode.
Horizontal Grounding Electrode.
Transmission Line Method Versus Antenna Theory Approach.
Measures for Quantifying the Transient Response of Grounding Electrodes.Human Exposure to Electrom agnetic Fields.
Environmental Risk of Electromagnetic Fields: General Considerations.
Assessment of Human Exposure to Electromagnetic Fields: Frequency and Time Domain Approach.
Human Exposure to Extremely Low Frequency (ELF) Electromagnetic Fields.
Exposure of Humans to Transient Radiation: Cylindrical Model of the Human Body.