Signal Integrity - Simplified（Eric Bogatin）.pdf

Publisher: Prentice Hall PTR Pub Date: September 15, 2003 ISBN: 0-13-066946-6 Pages: 608 Section 2.7. The Spectrum of an Ideal Square Wave Section 2.8. From the Frequency Domain to the Time Domain Section 2.9. Effect of Bandwidth on Rise Time Section 2.10. Bandwidth and Rise Time Section 2.11. What Does "Significant" Mean? Section 2.12. Bandwidth of Real Signals Section 2.13. Bandwidth and Clock Frequency Section 2.14. Bandwidth of a Measurement Section 2.15. Bandwidth of a Model Section 2.16. Bandwidth of an Interconnect Section 2.17. Bottom Line Chapter 3. Impedance and Electrical Models Section 3.1. Describing Signal-Integrity Solutions in Terms of Impedance Section 3.2. What Is Impedance? Section 3.3. Real vs. Ideal Circuit Elements Section 3.4. Impedance of an Ideal Resistor in the Time Domain Section 3.5. Impedance of an Ideal Capacitor in the Time Domain Section 3.6. Impedance of an Ideal Inductor in the Time Domain Section 3.7. Impedance in the Frequency Domain Section 3.8. Equivalent Electrical Circuit Models Section 3.9. Circuit Theory and SPICE Section 3.10. Introduction to Modeling Section 3.11. The Bottom Line Chapter 4. The Physical Basis of Resistance Section 4.1. Translating Physical Design into Electrical Performance Section 4.2. The Only Good Approximation for the Resistance of Interconnects Section 4.3. Bulk Resistivity Section 4.4. Resistance per Length Section 4.5. Sheet Resistance Section 4.6. The Bottom Line Chapter 5. The Physical Basis of Capacitance Section 5.1. Current Flow in Capacitors Section 5.2. The Capacitance of a Sphere Section 5.3. Parallel Plate Approximation Section 5.4. Dielectric Constant Section 5.5. Power and Ground Planes and Decoupling Capacitance Section 5.6. Capacitance per Length Section 5.7. 2D Field Solvers Section 5.8. Effective Dielectric Constant Section 5.9. The Bottom Line Chapter 6. The Physical Basis of Inductance Section 6.1. What Is Inductance? Section 6.2. Inductance Principle #1: There Are Circular Magneti