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Fundamentals of power integrity for computer platforms and systems /
"Power integrity is the study of power distribution from the source to the load and the system level issues that can occur across it. For computer systems, these issues can range from inside the silicon to across the board and may egress into other parts of the platform, including thermal, EMI,...
| Clasificación: | Libro Electrónico |
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| Autor principal: | |
| Formato: | Electrónico eBook |
| Idioma: | Inglés |
| Publicado: |
Hoboken, New Jersey :
John Wiley & Sons,
[2014]
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| Temas: | |
| Acceso en línea: | Texto completo (Requiere registro previo con correo institucional) |
Tabla de Contenidos:
- Cover; Title Page; Contents; Foreword by James L. Knighten; Preface; Acknowledgments; Acronyms; Chapter 1 Introduction to Power Integrity; 1.1 Definition for Power Integrity; 1.2 Historical Perspective on Power Integrity Drivers; 1.3 First Principles Analysis; 1.3.1 Steps to Solve Power Distribution Problems; 1.3.2 Limitations in the Analytical and Numerical Process; 1.4 Scope of the Text; References; Chapter 2 Introduction to Platform Power Conversion; 2.1 Power Distribution System; 2.1.1 Centralized and Distributed Distribution Systems; 2.1.2 Static Losses in the System Power Path. 2.2 Platform DC-to-DC Power Conversion2.2.1 Popular Converter Types; 2.2.2 The Linear Regulator; 2.2.3 The Buck Regulator; 2.2.4 LC Filter Operation; 2.2.5 Power Switch Basics; 2.2.6 The Controller; 2.2.7 Inductors; 2.2.8 Coupled Inductors; 2.2.9 Multi-phase Buck Converters; 2.2.10 The Tapped-Inductor Buck Converter; 2.3 Layout and Noise Considerations; 2.4 Summary; References; Problems; Chapter 3 Review of Electromagnetic Field and Circuit Representations; 3.1 Vectors and Scalars; 3.1.1 Coordinate Systems; 3.1.2 Vector Operations and Vector Calculus; 3.2 Static Fields; 3.2.1 Electrostatics. 3.2.2 Magneto-Statics3.2.3 Conduction and Resistance; 3.3 Maxwell's Equations; 3.3.1 The Wave Equation; 3.3.2 Lossless and Lossy Media; 3.4 Useful and Simple Circuit Extractions; 3.4.1 ``Power Plane'' Inductance; 3.4.2 Inductance of Two Circular Wires in Space; 3.4.3 Resistance between Two Vias in a Power Plane; 3.4.4 Notes on Applicability of Formulas; 3.5 Summary; References; Problems; Chapter 4 Power Distribution Network; 4.1 The Power Distribution Network; 4.2 PDN Elements; 4.2.1 PCB Network; 4.2.2 Socket Distribution; 4.2.3 Contact Resistance; 4.2.4 Package Distribution. 4.2.5 Decoupling Basics and Capacitors4.3 Impedance Distribution Analysis; 4.3.1 Analysis of a PDN Structure through First Principals; 4.3.2 Analysis of a Full PDN Structure; 4.4 Summary; References; Problems; Chapter 5 Power Integrity Time-Domain and Boundary Analysis; 5.1 Source and Load Modeling; 5.1.1 Source Representations; 5.1.2 Load Representations; 5.2 Time-Dependent Systems; 5.2.1 Voltage Bus Droop Boundary Conditions; 5.2.2 Voltage Bus Droop Boundary Analysis; 5.3 Impedance/Load Boundary Analysis; 5.4 Summary; References; Problems; Chapter 6 System Considerations for Power Integrity. 6.1 Power Loadline Fundamentals6.1.1 Loadline; 6.1.2 Tolerance Band and Voltage Guardband; 6.2 Noise Generation Considerations in Power Integrity; 6.2.1 Self-generated Power Bus Noise; 6.2.2 Coupled Power Bus Noise; 6.2.3 Simultaneous Switching Noise; 6.3 Power Noise Reduction Techniques; 6.4 EMI Considerations for Power Integrity; 6.5 Power Integrity PDN in System Measurements; 6.6 Summary; References; Problems; Chapter 7 Silicon Power Distribution and Analysis; 7.1 Silicon and Package Power Integrity; 7.1.1 Silicon Interconnection for Power Distribution.