Paul Clayton R. Introduction to Electromagnetic Compatibility

2nd edition. — Wiley-Interscience, 2006. — 1016 p. — ISBN 978-0471755005.As digital devices continue to be produced at increasingly lower costs and with higher speeds, the need for effective electromagnetic compatibility (EMC) design practices has become more critical than ever to avoid unnecessary costs in bringing products into compliance with governmental regulations. The Second Edition of this landmark text has been thoroughly updated and revised to reflect these major developments that affect both academia and the electronics industry. Readers familiar with the First Edition will find much new material, including:
Latest U.S. and international regulatory requirements;
PSpice used throughout the textbook to simulate EMC analysis solutions;
Methods of designing for Signal Integrity;
Fortran programs for the simulation of Crosstalk supplied on a CD;
OrCAD(r) PSpice(r) Release 10.0 and Version 8 Demo Edition software supplied on a CD;
The final chapter on System Design for EMC completely rewritten;
The chapter on Crosstalk rewritten to simplify the mathematics.
Detailed, worked-out examples are now included throughout the text. In addition, review exercises are now included following the discussion of each important topic to help readers assess their grasp of the material. Several appendices are new to this edition including Phasor Analysis of Electric Circuits, The Electromagnetic Field Equations and Waves, Computer Codes for Calculating the Per-Unit-Length Parameters and Crosstalk of Multiconductor Transmission Lines, and a SPICE (PSPICE) tutorial.
Now thoroughly updated, the Second Edition of Introduction to Electromagnetic Compatibility remains the textbook of choice for university/college EMC courses as well as a reference for EMC design engineers.Introduction to Electromagnetic Compatibility (EMC).
Aspects of EMC.
History of EMC.
Examples.
Electrical Dimensions and Waves.
Decibels and Common EMC Units.EMC Requirements for Electronic Systems.
Governmental Requirements.
Additional Product Requirements.
Design Constraints for Products.
Advantages of EMC Design.Signal Spectra — the Relationship between the Time Domain and the Frequency Domain.
Periodic Signals.
Spectra of Digital Wave forms.
Spectrum Analyzers.
Representation of Nonperiodic Waveforms.
Representation of Random (Data) Signals.
Use of SPICE (PSPICE) In Fourier Analysis.Transmission Lines and Signal Integrity.
The Transmission-Line Equations.
The Per-Unit-Length Parameters.
The Time-Domain Solution.
High-Sp eed Digital Int erconnects and Signal Integrity.
Sinusoidal Excitation of the Line and the Phasor Solution.
Lumped-Circuit Approximate Models.Nonideal Behavior of Components.
Wires.
Printed Circuit Board (PCB) Lands.
Effect of Component Leads.
Resistors.
Capacitors.
Inductors.
Ferromagnetic Materials—Saturation and Frequency Response.
Ferrite Beads.
Common-Mode Chokes.
Electromechanical Devices.
Digital Circuit Devices.
Effect of Component Variability.
Mechanical Switches.Conducted Emissions and Susceptibility.
Measurement of Conducted Emissions.
Power Supply Filters.
Power Supplies.
Power Supply and Filter Placement.
Conducted Susceptibility.Antennas.
Elemental Dipole Antennas.
The Half-Wave Dipole and Quarter-Wave Monopole Antennas.
Antenna Arrays.
Characterization of Antennas.
The Friis Transmission Equation.
Effects of Reflections.
Broadband Measurment Antennas.Radiated Emissions and Susceptibility.
Simple Emissi on Models for Wires and PCB Lands.
Simple Susceptibility Models for Wires and PCB Lands.Crosstalk.
Three-Conductor Transmission Lines and Crosstalk.
The Transmission-Line Equations for Lossless Lines.
The Per-Unit-Length Parameters.
The Inductive–Capacitive Coupling Approximate Model.
Lumped-Circuit Approximate Models.
An Exact SPICE (PSPICE) Model for Lossless, Coupled Lines.
Shielded Wires.
Twisted Wires.Shielding.
Shielding Effectiveness.
Shielding Effectiveness: Far-Field Sources.
Shielding Effectiveness: Near-Field Sources.
Low-Frequency, Magnetic Field Shielding.
Effect of Apertures.System Design for EMC.
Changing the Way We Think about Electrical Phenomena.
What Do We Mean by the Term “Ground”?
Printed Circuit Board (PCB) Design.
System Configuration and Design.
Diagnostic Tools.Appendixes:
A The Phasor Solution Method.
The Electromagnetic Field Equations and Waves.
Computer Codes for Calculating the Per-Unit-Length.
A SPICE (PSPICE) Tutorial.References.
Index.