Digital circuit boards : mach 1 GHz

Digital circuit boards mach 1 GHz

A unique, practical approach to the design of high-speed digital circuit boards The demand for ever-faster digital circuit designs is beginning to render the circuit theory used by engineers ineffective. Digital Circuit Boards presents an alternative to the circuit theory approach, emphasizing ener...

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Detalles Bibliográficos
Autor principal: Morrison, Ralph (-)
Formato: Libro electrónico
Idioma:Inglés
Publicado: Hoboken, N.J. : John Wiley & Sons, Inc c2012.
Edición:1st edition
Materias:
Digital electronics.
Logic design.
Integrated circuits.
Ver en Biblioteca Universitat Ramon Llull:https://discovery.url.edu/permalink/34CSUC_URL/1im36ta/alma991009628786006719
Tabla de Contenidos:
  • DIGITAL CIRCUIT BOARDS; CONTENTS; Preface; 1 BASICS; 1.1 Introduction; 1.2 Why the Field Approach is Important; 1.3 The Role of Circuit Analysis; 1.4 Getting Started; 1.5 Voltage and the Electric Field; 1.6 Current; 1.7 Capacitance; 1.8 Mutual and Self-Capacitance; 1.9 E Fields Inside Conductors; 1.10 The D Field; 1.11 Energy Storage in a Capacitor; 1.12 The Energy Stored in an Electric Field; 1.13 The Magnetic Field; 1.14 Rise Time/Fall Time; 1.15 Moving Energy into Components; 1.16 Faraday's Law; 1.17 Self- and Mutual Inductance; 1.18 Poynting's Vector; 1.19 Fields at DC; Glossary
  • 2 TRANSMISSION LINES 2.1 Introduction; 2.2 Some Common Assumptions; 2.3 Transmission Line Types; 2.4 Characteristic Impedance; 2.5 Wave Velocity; 2.6 Step Waves on a Properly Terminated Line; 2.7 The Open Circuited Transmission Line; 2.8 The Short Circuited Transmission Line; 2.9 Waves that Transition between Lines with Different Characteristic Impedances; 2.10 Nonlinear Terminations; 2.11 Discharging a Charged Open Transmission Line; 2.12 Ground/Power Planes; 2.13 The Ground and Power Planes as a Tapered Transmission Line; 2.14 Pulling Energy from a Tapered Transmission Line (TTL)
  • 2.15 The Energy Flow Through Cascaded (Series) Transmission Lines 2.16 An Analysis of Cascaded Transmission Lines; 2.17 Series (Source) Terminating a Transmission Line; 2.18 Parallel (Shunt) Terminations; 2.19 Stubs; 2.20 Decoupling Capacitor as a Stub; 2.21 Transmission Line Networks; 2.22 The Network Program; 2.23 Measuring Characteristic Impedance; Glossary; 3 RADIATION AND INTERFERENCE COUPLING; 3.1 Introduction; 3.2 The Nature of Fields in Logic Structures; 3.3 Classical Radiation; 3.4 Radiation from Step Function Waves; 3.5 Common Mode and Normal Mode
  • 3.6 The Radiation Pattern along a Transmission Line 3.7 Notes on Radiation; 3.8 The Cross Coupling Process (Cross Talk); 3.9 Magnetic Component of Cross Coupling; 3.10 Capacitive Component of Cross Coupling; 3.11 Cross Coupling Continued; 3.12 Cross Coupling between Parallel Transmission Lines of Equal Length; 3.13 Radiation from Board Edges; 3.14 Ground Bounce; 3.15 Susceptibility; Glossary; 4 ENERGY MANAGEMENT; 4.1 Introduction; 4.2 The Power Time Constant; 4.3 Capacitors; 4.4 The Four-Terminal Capacitor or DTL; 4.5 Types of DTLs; 4.6 Circuit Board Resonances; 4.7 Decoupling Capacitors
  • 4.8 The Board Decoupling Problem 4.9 The IC Decoupling Problem; 4.10 Comments on Energy Management; 4.11 Skin Effect; 4.12 Dielectric Losses; 4.13 Split Ground/Power Planes; 4.14 The Analog/digital Interface Problem; 4.15 Power Dissipation; 4.16 Traces through Conducting Planes; 4.17 Trace Geometries that Reduce Termination Resistor Counts; 4.18 The Control of Connecting Spaces; 4.19 Another way to look at Energy Flow in Transmission Lines; Glossary; 5 SIGNAL INTEGRITY ENGINEERING; 5.1 Introduction; 5.2 The Envelope of Permitted Logic Levels; 5.3 Net Lists; 5.4 Noise Budgets
  • 5.5 Logic Level Variation

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