A Landmark text thoroughly updated, including a new CD

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.

An Instructor's Manual presenting detailed solutions to all the
problems in the book is available from the Wiley editorial
department.

CLAYTON R. PAUL, PHD, is Professor and Sam Nunn Chair of Aerospace Systems Engineering, Department of Electrical and Computer Engineering, Mercer University. He is also Emeritus Professor of Electrical Engineering at the University of Kentucky, where he served on the fac-ulty for twenty-seven years. Dr. Paul is the author of twelve textbooks in electrical engineering, has contributed numerous chapters to engineering handbooks and reference texts, and has published numerous technical papers in scientific journals and symposia. He is a Fellow of the IEEE and a Honorary Life Member of the IEEE EMC Society.

Zusammenfassung
A Landmark text thoroughly updated, including a new CD

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.

An Instructor's Manual presenting detailed solutions to all the problems in the book is available from the Wiley editorial department.

Preface xvii

1 Introduction to Electromagnetic Compatibility (EMC) 1

1.1 Aspects of EMC 3

1.2 History of EMC 10

1.3 Examples 12

1.4 Electrical Dimensions and Waves 14

1.5 Decibels and Common EMC Units 23

Problems 43

References 48

2 EMC Requirements for Electronic Systems 49

2.1 Governmental Requirements 50

2.2 Additional Product Requirements 79

2.3 Design Constraints for Products 82

2.4 Advantages of EMC Design 84

Problems 86

References 89

3 Signal Spectra—the Relationship between the Time Domain and the Frequency Domain 91

3.1 Periodic Signals 91

3.3 Spectrum Analyzers 142

3.4 Representation of Nonperiodic Waveforms 148

3.5 Representation of Random (Data) Signals 151

3.6 Use of SPICE (PSPICE) In Fourier Analysis 155

Problems 167

References 175

4 Transmission Lines and Signal Integrity 177

4.1 The Transmission-Line Equations 181

4.2 The Per-Unit-Length Parameters 184

4.3 The Time-Domain Solution 204

4.4 High-Speed Digital Interconnects and Signal Integrity 225

4.5 Sinusoidal Excitation of the Line and the Phasor Solution 260

4.6 Lumped-Circuit Approximate Models 283

Problems 287

References 297

5 Nonideal Behavior of Components 299

5.1 Wires 300

5.2 Printed Circuit Board (PCB) Lands 312

5.3 Effect of Component Leads 315

5.4 Resistors 317

5.5 Capacitors 325

5.6 Inductors 336

5.7 Ferromagnetic Materials—Saturation and Frequency Response 340

5.8 Ferrite Beads 343

5.9 Common-Mode Chokes 346

5.10 Electromechanical Devices 352

5.11 Digital Circuit Devices 357

5.12 Effect of Component Variability 358

5.13 Mechanical Switches 359

Problems 369

References 375

6 Conducted Emissions and Susceptibility 377

6.1 Measurement of Conducted Emissions 378

6.2 Power Supply Filters 385

6.3 Power Supplies 401

6.4 Power Supply and Filter Placement 414

6.5 Conducted Susceptibility 416

Problems 416

References 419

7 Antennas 421

7.1 Elemental Dipole Antennas 421

7.2 The Half-Wave Dipole and Quarter-Wave Monopole Antennas 429

7.3 Antenna Arrays 440

7.4 Characterization of Antennas 448

7.5 The Friis Transmission Equation 466

7.6 Effects of Reflections 470

7.7 Broadband Measurment Antennas 486

Problems 494

References 501

8 Radiated Emissions and Susceptibility 503

8.1 Simple Emission Models for Wires and PCB Lands 504

8.2 Simple Susceptibility Models for Wires and PCB Lands 533

Problems 550

References 556

9 Crosstalk 559

9.1 Three-Conductor Transmission Lines and Crosstalk 560

9.2 The Transmission-Line Equations for Lossless Lines 564

9.3 The Per-Unit-Length Parameters 567

9.4 The Inductive–Capacitive Coupling Approximate Model 595

9.5 Lumped-Circuit Approximate Models 624