LEADER 08026nam 2200721 a 450 001 9910877672003321 005 20200520144314.0 010 $a1-118-21068-9 010 $a1-282-13710-7 010 $a9786612137105 010 $a0-470-42389-7 010 $a0-470-42388-9 024 7 $a10.1002/9780470423899 035 $a(CKB)1000000000719466 035 $a(EBL)427609 035 $a(SSID)ssj0000097846 035 $a(PQKBManifestationID)11137654 035 $a(PQKBTitleCode)TC0000097846 035 $a(PQKBWorkID)10131938 035 $a(PQKB)11117577 035 $a(MiAaPQ)EBC427609 035 $a(CaBNVSL)mat05361024 035 $a(IDAMS)0b00006481178830 035 $a(IEEE)5361024 035 $a(OCoLC)352828514 035 $a(CaSebORM)9780470192351 035 $a(PPN)179236431 035 $a(OCoLC)810071431 035 $a(OCoLC)ocn810071431 035 $a(EXLCZ)991000000000719466 100 $a20080623d2009 uy 0 101 0 $aeng 135 $aur|n|---||||| 181 $ctxt 182 $cc 183 $acr 200 10$aAdvanced signal integrity for high-speed digital designs /$fStephen H. Hall, Howard L. Heck 205 $a1st edition 210 $aHoboken, N.J. $cJohn Wiley & Sons$d2009 215 $a1 online resource (680 p.) 300 $aDescription based upon print version of record. 311 $a0-470-19235-6 320 $aIncludes bibliographical references and index. 327 $aPreface -- 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. 327 $a7.5 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. 327 $a14.11 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. 330 $aA 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. 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. 606 $aDigital electronics 606 $aLogic design 606 $aSignal integrity (Electronics) 615 0$aDigital electronics. 615 0$aLogic design. 615 0$aSignal integrity (Electronics) 676 $a621.381 700 $aHall$b Stephen H$0118939 701 $aHeck$b Howard L$01663647 801 0$bMiAaPQ 801 1$bMiAaPQ 801 2$bMiAaPQ 906 $aBOOK 912 $a9910877672003321 996 $aAdvanced signal integrity for high-speed digital designs$94021114 997 $aUNINA