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Prentice Hall Modern Semiconductor Design Ser.: Signal Integrity - Simplified by Eric Bogatin (2003, Hardcover)
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SIGNAL INTEGRITY - SIMPLIFIED By Eric Bogatin - Hardcover **BRAND NEW**.
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About this product
Product Identifiers
PublisherPrentice Hall PTR
ISBN-100130669466
ISBN-139780130669469
eBay Product ID (ePID)2419945
Product Key Features
Number of Pages608 Pages
LanguageEnglish
Publication NameSignal Integrity-Simplified
SubjectSignals & Signal Processing, Electronics / General
Publication Year2003
TypeTextbook
Subject AreaTechnology & Engineering
AuthorEric Bogatin
SeriesPrentice Hall Modern Semiconductor Design Ser.
FormatHardcover
Dimensions
Item Height1.1 in
Item Weight38.3 Oz
Item Length9.4 in
Item Width7.3 in
Additional Product Features
Intended AudienceScholarly & Professional
LCCN2003-049870
Dewey Edition21
IllustratedYes
Dewey Decimal621.3815
Table Of ContentPreface. 1. Signal Integrity Is in Your Future. What Is Signal Integrity? Signal Quality on a Single Net. Cross Talk. Rail-Collapse Noise. Electromagnetic Interference (EMI). Two Important Signal Integrity Generalizations. Trends in Electronic Products. The Need for a New Design Methodology. A New Product Design Methodology. Simulations. Modeling and Models. Creating Circuit Models from Calculation. Three Types of Measurements. The Role of Measurements. The Bottom Line.2. Time and Frequency Domains. The Time Domain. Sine Waves in the Frequency Domain. Shorter Time to a Solution in the Frequency Domain. Sine Wave Features. The Fourier Transform. The Spectrum of a Repetitive Signal. The Spectrum of an Ideal Square Wave. From the Frequency Domain to the Time Domain. Effect of Bandwidth on Rise Time. Bandwidth and Rise Time. What Does "Significant" Mean? Bandwidth of Real Signals. Bandwidth and Clock Frequency. Bandwidth of a Measurement. Bandwidth of a Model. Bandwidth of an Interconnect. Bottom Line.3. Impedance and Electrical Models. Describing Signal-Integrity Solutions in Terms of Impedance. What Is Impedance? Real vs Ideal Circuit Elements. Impedance of an Ideal Resistor in the Time Domain. Impedance of an Ideal Capacitor in the Time Domain. Impedance of an Ideal Inductor in the Time Domain. Impedance in the Frequency Domain. Equivalent Electrical Circuit Models. Circuit Theory and SPICE. Introduction to Modeling. The Bottom Line.4. The Physical Basis of Resistance. Translating Physical Design into Electrical Performance. The Only Good Approximation for the Resistance of Interconnects. Bulk Resistivity. Resistance per Length. Sheet Resistance. The Bottom Line.5. The Physical Basis of Capacitance. Current Flow in Capacitors. The Capacitance of a Sphere. Parallel Plate Approximation. Dielectric Constant. Power and Ground Planes and Decoupling Capacitance. Capacitance per Length. 2D Field Solvers. Effective Dielectric Constant. The Bottom Line.6. The Physical Basis of Inductance. What Is Inductance? Inductance Principle #1: There Are Circular Magnetic-Field Line Loops around All Currents. Inductance Principle #2: Inductance Is the Number of Webers of Field Line Loops around a Conductor per Amp of Current through It. Self-Inductance and Mutual Inductance. Inductance Principle #3: When the Number of Field Line Loops around a Conductor Changes, There Will Be a Voltage Induced across the Ends of the Conductor. Partial Inductance. Effective, Total, or Net Inductance and Ground Bounce. Loop Self- and Mutual Inductance. The Power-Distribution System (PDS) and Loop Inductance. Loop Inductance per Square of Planes. Loop Inductance of Planes and Via Contacts. Loop Inductance of Planes with a Field of Clearance Holes. Loop Mutual Inductance. Equivalent Inductance. Summary of Inductance. Current Distributions and Skin Depth. High-Permeability Materials. Eddy Currents. The Bottom Line.7. The Physical Basis of Transmission Lines. Forget the Word Ground. The Signal. Uniform Transmission Lines. The Speed of Electrons in Copper. The Speed of a Signal in a Transmission Line. Spatial Extent of the Leading Edge. "Be the Signal". The Instantaneous Impedance of a Transmission Line. haracteristic Impedance and Controlled Impedance. Famous Characteristic Impedances. The Impedance of a Transmission Line. Driving a Transmission Line. Return Paths. When Return Paths Switch Reference Planes. A First-Order Model of a Transmission Line. Calculating Characteristic Impedance with Approximations. Calculating the Characteristic Impedance with a 2D Field Solver. An n-Section Lumped Circuit Model. Frequency Variation of the Characteristic Impedance. The Bottom Line.8. Transmission Lines and Reflections. Reflections at Impedance Changes. Why Are There Reflections? Reflections from Resistive Loads. Source Impedance. Bounce Diagrams. Simulating Reflected Waveforms. Measuring Reflections with a TDR. Trans
SynopsisThe book presents the important concepts and topics of signal integrity, such as impedance, bandwidth, characteristic impedance, inductance, skin depth and cross talk at an introductory level showing the underlying mechanisms. This book would introduce the reader to each of these terms and what they really mean, without complex mathematics., This book describes in the simplest possible terms, the signal integrity problems and the fundamental principles needed to understand how the physical design influences signal integrity. Most easily defined, signal integrity is all about how the physical design of the interconnects - printed circuit board traces, connectors, IC packages and cables - corrupt the perfect, pristine signals coming off the chips. The electrical properties of the interconnects play a key role in all electronic products operating above 50 MHz clock frequency, such as computers, wireless, rf and telecommunications products. Interconnects can degrade the electrical performance of a system in four ways: ringing, cross talk, noise in the power and ground distribution network and electromagnetic interference (EMI). These signal integrity problems can be reduced to acceptable levels by careful design of the circuit board layout, materials selection and component design and selection. Any product designer that touches the product can have an impact on signal integrity. The key differentiator between our book and all the others written on signal integrity, is the starting level for the material. Most books either present a lot of mathematical derivation or present formulas as facts, merely describing what they are. Bogatin's book offers explanations that will feed the intuition of the engineers, without hiding behind the equations.
LC Classification NumberTK5102.9.B58 2003
