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Book
xvii, 660 p. : ill. ; 25 cm.
  • Preface. Acknowledgments. Chapter 1: Introduction: The importance of signal integrity. 1.1 Computing Power: Past and Future. 1.2 The problem. 1.3 The Basics. 1.4 A new realm of bus design. 1.5 Scope. 1.6 Summary. 1.7 References. Chapter 2: Electromagnetic Fundamentals for Signal Integrity. 2.1 Introduction. 2.2 Maxwell's Equations. 2.3 Common Vector Operators. 2.4 Wave Propagation. 2.5 Electrostatics. 2.6 Magnetostatics. 2.7 Power Flow and the Poynting Vector. 2.8 Reflections of Electromagnetic Waves. 2.9 References. 2.10 Problems. Chapter 3: Ideal Transmission Line Fundamentals. 3.1 Transmission Line Structures. 3.2 Wave propagation on loss free transmission lines. 3.3 Transmission line properties. 3.4 Transmission line parameters for the loss free case. 3.5 Transmission line reflections. 3.6 Time domain Reflectometry. 3.7 References. 3.8 Problems. Chapter 4: Crosstalk. 4.1 Mutual Inductance and Capacitance. 4.2 Coupled Wave Equations. 4.3 Coupled Line Analysis. 4.4 Modal Analysis. 4.5 Crosstalk Minimization. 4.6 Summary. 4.7 References. 4.8 Problems. Chapter 5: Non-ideal conductor models for transmission lines. 5.1 Signals propagating in an unbounded conductive media. 5.2 Classic conductor model for transmission lines. 5.3 Surface Roughness. 5.4 Transmission line parameters with a non-ideal conductor. 5.5 Problems. Chapter 6: Electrical properties of dielectrics. 6.1 Polarization of dielectrics. 6.2 Classification of dielectric materials. 6.3 Frequency dependent dielectric behavior. 6.4 Properties of a physical dielectric model. 6.5 The fiber-weave effect. 6.6 Environmental variation in dielectric behavior. 6.7 Transmission line parameters for lossy dielectrics and realistic conductors. 6.8 References. 6.9 Problems. Chapter 7: Differential signaling. 7.1 Removal of common mode noise. 7.2 Differential Crosstalk. 7.3 Virtual reference plane. 7.4 Propagation of Modal Voltages. 7.5 Common terminology. 7.6 Drawbacks of differential signaling. 7.7 References. 7.8 Problems. Chapter 8: Mathematical Requirements of Physical Channels. 8.1 Frequency domain effects in time domain simulations. 8.2 Requirements for a physical Channel. 8.3 References. 8.4 Problems. Chapter 9: Network Analysis for Digital Engineers. 9.1 High frequency voltage and current waves. 9.2 Network Theory. 9.3 Properties of Physical S-parameters. 9.4 References. 9.5 Problems. Chapter 10: Topics in High-Speed Channel Modeling. 10.1 Creating a physical transmission line mode. 10.2 Non-Ideal Return Paths. 10.3 Vias. 10.4 References. 10.5 Problems. Chapter 11: I/O Circuits and Models. 11.1 Introduction. 11.2 Push-Pull Transmitters. 11.3 CMOS Receivers. 11.4 ESD Protection Circuits. 11.5 On-Chip Termination. 11.6 Bergeron Diagrams. 11.7 Open Drain Transmitters. 11.8 Differential Current Mode Transmitters. 11.9 Low Swing/Differential Receivers. 11.10 IBIS Models. 11.11 Summary. 11.12 References. 11.13 Problems. Chapter 12: Equalization. 12.1 Introduction. 12.2 Continuous Time Linear Equalizers. 12.3 Discrete Linear Equalizers. 12.4 Decision Feedback Equalization. 12.5 Summary. 12.6 References. 12.7 Problems. Chapter 13: Modeling and Budgeting of Timing Jitter and Noise. 13.1 The Eye Diagram. 13.2 Bit Error Rate. 13.3 Jitter Sources and Budgets. 13.4 Noise Sources and Budgets. 13.5 Peak Distortion Analysis Methods. 13.6 Summary. 13.7 References. 13.8 Problems. Chapter 14: System Analysis Using Response Surface Modeling. 14.1 Introduction. 14.2 Case Study: 10 Gb/s differential PCB interface. 14.3 RSM Construction by Least Squares Fitting. 14.4 Measures of Fit. 14.5 Significance Testing. 14.6 Confidence Intervals. 14.7 Sensitivity Analysis and Design Optimization. 14.8 Defect Rate Prediction Using Monte Carlo Simulation. 14.9 Additional RSM Considerations. 14.10 Summary. 14.11 References. 14.12 Problems. Appendix A: Useful formulae, identities, units and constants. Appendix B: 4-port Conversions between T and S-parameters. Appendix C: Critical values of the F-statistic. Appendix D: Critical values of the t-statistic. Appendix E: Derivation of the internal inductance using the Hilbert Transform.
  • (source: Nielsen Book Data)9780470192351 20160528
This title offers a synergistic approach to signal integrity for high-speed digital design. This book is designed to provide contemporary readers with an understanding of the emerging high-speed signal integrity issues that are creating roadblocks in digital design. Written by the foremost experts on the subject, it leverages concepts and techniques from non-related fields such as applied physics and microwave engineering and applies them to high-speed digital design-creating the optimal combination between theory and practical applications. Following an introduction to the importance of signal integrity, chapter coverage includes: electromagnetic fundamentals for signal integrity; transmission line fundamentals; crosstalk Non-ideal conductor models, including surface roughness and frequency-dependent inductance; frequency-dependent properties of dielectrics; differential signaling; mathematical requirements of physical channels; S-parameters for digital engineers; Non-ideal return paths and via resonance I/O circuits and models; Equalization Modeling and budgeting of timing jitter and noise; and, system analysis using response surface modeling. Each chapter includes many figures and numerous examples to help readers relate the concepts to everyday design and concludes with problems for readers to test their understanding of the material. Advanced Signal Integrity for High-Speed Digital Designs is suitable as a textbook for graduate-level courses on signal integrity, for programs taught in industry for professional engineers, and as a reference for the high-speed digital designer.
(source: Nielsen Book Data)9780470192351 20160528
Engineering Library (Terman), eReserve
EE-273-01
Book
xxx, 766 p. : ill. ; 25 cm.
  • Preface. Glossary of Symbols. 1. Fundamentals. Impedance of Linear, Time-Invariant, Lumped-Element Circuits. Power Ratios. Rules of Scaling. The Concept of Resonance. Extra for Experts: Maximal Linear System Response to a Digital Input. 2. Transmission Line Parameters. Telegrapher's Equations. Derivation of Telegrapher's Equations. Ideal Transmission Line. DC Resistance. DC Conductance. Skin Effect. Skin-Effect Inductance. Modeling Internal Impedance. Concentric-Ring Skin-Effect Model. Proximity Effect. Surface Roughness. Dielectric Effects. Impedance in Series with the Return Path. Slow-Wave Mode On-Chip. 3. Performance Regions. Signal Propagation Model. Hierarchy of Regions. Necessary Mathematics: Input Impedance and Transfer Function. Lumped-Element Region. RC Region. LC Region (Constant-Loss Region). Skin-Effect Region. Dielectric Loss Region. Waveguide Dispersion Region. Summary of Breakpoints Between Regions. Equivalence Principle for Transmission Media. Scaling Copper Transmission Media. Scaling Multimode Fiber-Optic Cables. Linear Equalization: Long Backplane Trace Example. Adaptive Equalization: Accelerant Networks Transceiver. 4. Frequency-Domain Modeling. Going Nonlinear. Approximations to the Fourier Transform. Discrete Time Mapping. Other Limitations of the FFT. Normalizing the Output of an FFT Routine. Useful Fourier Transform-Pairs. Effect of Inadequate Sampling Rate. Implementation of Frequency-Domain Simulation. Embellishments. Checking the Output of Your FFT Routine. 5. Pcb (printed-circuit board) Traces. Pcb Signal Propagation. Limits to Attainable Distance. Pcb Noise and Interference. Pcb Connectors. Modeling Vias. The Future of On-Chip Interconnections. 6. Differential Signaling. Single-Ended Circuits. Two-Wire Circuits. Differential Signaling. Differential and Common-Mode Voltages and Currents. Differential and Common-Mode velocity. Common-Mode Balance. Common-Mode Range. Differential to Common-Mode Conversion. Differential Impedance. Pcb Configurations. Pcb Applications. Intercabinet Applications. LVDS Signaling. 7. Generic Building-Cabling Standards. Generic Cabling Architecture. SNR Budgeting. Glossary of Cabling Terms. Preferred Cable Combinations. FAQ: Building-Cabling Practices. Crossover Wiring. Plenum-Rated Cables. Laying cables in an Uncooled Attic Space. FAQ: Older Cable Types. 8. 100-Ohm Balanced Twisted-Pair Cabling. UTP Signal Propagation. UTP Transmission Example: 10BASE-T. UTP Noise and Interference. UTP Connectors. Issues with Screening. Category-3 UTP at Elevated Temperature. 9. 150-Ohm STP-A Cabling. 150-( STP-A Signal Propagation. 150-( STP-A Noise and Interference. 150-( STP-A: Skew. 150-( STP-A: Radiation and Safety. 150-( STP-A: Comparison with UTP. 150-( STP-A Connectors. 10. Coaxial Cabling. Coaxial Signal Propagation. Coaxial Cable Noise and Interference. Coaxial Cable Connectors. 11. Fiber-Optic Cabling. Making Glass Fiber. Finished Core Specifications. Cabling the Fiber. Wavelengths of Operation. Multimode Glass Fiber-Optic Cabling. Single-Mode Fiber-Optic Cabling. 12. Clock Distribution. Extra Fries, Please. Arithmetic of Clock Skew. Clock Repeaters. Stripline vs. Microstrip Delay. Importance of Terminating Clock Lines. Effect of Clock Receiver Thresholds. Effect of Split Termination. Intentional Delay Adjustments. Driving Multiple Loads with Source Termination. Daisy-Chain Clock Distribution. The Jitters. Power Supply Filtering for Clock Sources, Repeaters, and PLL Circuits. Intentional Clock Modulation. Reduced-Voltage Signaling. Controlling Crosstalk on Clock Lines. Reducing Emissions. 13. Time-Domain Simulation Tools and Methods. Ringing in a New Era. Signal Integrity Simulation Process. The Underlying Simulation Engine. IBIS (I/O Buffer Information Specification). IBIS: History and Future Direction. IBIS: Issues with Interpolation. IBIS: Issues with SSO Noise. Nature of EMC Work. Power and Ground Resonance. Collected References. Points to Remember. Appendix A. Building a Signal Integrity Department. Appendix B. Calculation of Loss Slope. Appendix C. Two-Port Analysis. Appendix D. Accuracy of Pi Model. Appendix E. erf( ). Index.
  • (source: Nielsen Book Data)9780130844088 20160527
Raves for Dr. Johnson's previous classic, High-Speed Digital Design! " ...one of the finest efforts to come along in the field of applied high-speed digital design because of its focus on providing tools for the whole design team bringing a high-speed product to life. For all the PCB designers and circuit designers out there, buy it; read it; keep it." -- Dan Baumgartner, Printed Circuit Design Faster and farther: State-of-the-art signal transmission techniques In High-Speed Signal Propagation, Howard Johnson and Martin Graham bring together state-of-the-art techniques for building digital interconnections that can transmit faster, farther, and more efficiently than ever before. Packed with new examples and never-before-published high-speed design guidance, this book offers a complete and unified theory of signal propagation for all metallic media, from cables to pcb traces to chips.Coverage includes: *Managing tradeoffs between speed and distance *Physical theory of signal impairments: skin and proximity effects, dielectric loss, surface roughness, and non-TEM mode propagation *Generalized frequency- and step-response models *Calculation of time-domain waveforms from frequency-domain transfer functions *Differential signaling: Edge-coupled and broadside-coupled differential pairs, bends, intra-pair skew, differential trace geometry impedance, crosstalk, and radiation *Inter-cabinet connections: Coax, twisted-pair, fiber, equalizers, and LAN building wiring *Clock distribution: Special requirements, repeaters, multi-drop clock distribution, jitter, and power filtering *Simulation: Frequency domain simulation methods, Spice, and IBIS.
(source: Nielsen Book Data)9780130844088 20160527
Engineering Library (Terman), eReserve
EE-273-01
Book
xxiv, 663 p. : ill. ; 26 cm.
  • 1. Introduction to digital systems engineering-- 2. Packaging of digital systems-- 3. Modeling and analysis of wires-- 4. Circuits-- 5. Power distribution-- 6. Noise in digital systems-- 7. Signalling conventions-- 8. Advanced signalling techniques-- 9. Timing conventions-- 10. Synchronization-- 11. Signalling circuits-- 12. Timing circuits-- Index.
  • (source: Nielsen Book Data)9780521592925 20160528
What makes some computers slow? Why do some digital systems operate reliably for years while others fail mysteriously every few hours? How can some systems dissipate kilowatts while others operate off batteries? These questions of speed, reliability, and power are all determined by the system-level electrical design of a digital system. Digital Systems Engineering presents a comprehensive treatment of these topics. It combines a rigorous development of the fundamental principles in each area with real-world examples of circuits and methods. The book not only serves as an undergraduate textbook, filling the gap between circuit design and logic design, but can also help practising digital designers keep pace with the speed and power of modern integrated circuits. The techniques described in this book, once used only in supercomputers, are essential to the correct and efficient operation of any type of digital system.
(source: Nielsen Book Data)9780521592925 20160528
Engineering Library (Terman)
EE-273-01
Book
408 p.
  • 1. Passive Device Modeling. 2. Circuit Simulation with SPICE. 3. System Noise Margin. 4. Digital Chip and Board Technologies. 5. Transmission Line Basics. 6. Signal Reflection Noise and Termination Schemes. 7. Crosstalk Noise. 8. Simultaneous Switching Noise. 9. Timing Analysis in Digital Circuits. 10. The Coaxial Cable. 11. Cooling and Reliability. 12. Electrical Design Processes.
  • (source: Nielsen Book Data)9780132134712 20160527
For junior-senior- and graduate-level courses in digital circuits and digital electronics. Focused on the analog analysis of digital circuits, this text bridges the gap between theory and the actual design of practical high-speed, high-density computer circuits -- with an emphasis on the various noises that the designer must be aware of in order to identify preventive measures and make appropriate trade-offs.
(source: Nielsen Book Data)9780132134712 20160527
Engineering Library (Terman)
EE-273-01
Book
xi, 447 p. : ill. ; 25 cm.
  • Fundamentals-- high speed properties of logic gates-- measurement techniques-- transmission lines-- ground planes and layer stacking-- terminations-- VIAS-- power systems-- connectors-- ribbon cables-- clock distribution-- clock oscillators.
  • (source: Nielsen Book Data)9780133957242 20160528
Focusing on a combination of digital and analog circuit theory, this comprehensive volume will help engineers who work with digital systems, shorten their product development cycles, and fix their latest high-speed design problems. *Covers signal reflection, crosstalk, and noise problems that occur in high-speed digtal machines (above 10 megahertz). *lncludes checklists that ask the questions an experienced designer would about a new system. *Offers useful formulas for inductance, capacitance, resistance, rise time, and Q. *Explains the trade-offs between signal cross talk, mechanical fabrication of tolerances, and trace routing density. *Presents a methodology for determining how many layrs will be required to route a printed circuit board.
(source: Nielsen Book Data)9780133957242 20160528
Engineering Library (Terman)
EE-273-01