Digital Transmission Lines
Computer Modelling and Analysis
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48 725 Ft (46 405 Ft + 5% áfa)
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48 725 Ft
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A termék adatai:
- Kiadó OUP USA
- Megjelenés dátuma 1998. június 4.
- ISBN 9780195112924
- Kötéstípus Keménykötés
- Terjedelem368 oldal
- Méret 243x194x17 mm
- Súly 819 g
- Nyelv angol
- Illusztrációk numerous line figures, plus CD 0
Kategóriák
Rövid leírás:
Digital Transmission Lines provides new analysis, simulation and design tools for engineers who design digital circuits. Featuring a collection of algorithms that the author has used successfully for over 20 years, it explains methods used to simulate multi-wire transmission line signal propagation. The text covers transmission line fundamentals, circuit solutions at line terminations, propagation in layered media, transmission line parameter determination,
and simulation of skin effect. An accompanying CD-ROM contains all source codes from the text as well as executable demo versions of commercial CAD codes that illustrate use of the principles in the book. Suitable for a graduate textbook, this volume should be on every digital circuit designer's
bookshelf.
Hosszú leírás:
The most important contribution of this book is its method of simulating crosstalk and providing design tools for its control between closely spaced traces on a circuit board. The approach is unique to this book. It begins with an introduction to the transmission line equations and progresss to the solution for the signals on networks of multi-wire lined in layered dielectric media. It further develops a method (and supplies computer code) to include the skin effect
in the propagation algorithm. All solution algorithms for digital signals are time stepping algorithms that lend themselves to intuitive understanding. The book is in five parts: I. Transmission Line Fundamentals, II. Circuit Solutions at Line Terminations, III. Propagation in Layered Media, IV.
Transmission Line Parameter Determination, and V. Simulation of Skin Effect. Methods are explained that the author has successfully used to simulate multi-wire transmission line signal propagation. A contemporary need for these methods exists among those who design or simulate transmission lines that carry digital signals. Such engineers must have both an understanding of the mechanisms of propagation and crosstalk and a means of quantitatively evaluating them. The book provides expanations to
enhance understanding of signal propagation and crosstalk amd mathematical algorithms for their numerical evaluation. It also provides design methods for reducing crosstalk between traces on a multi-layered circuit board. Numerous exercises, hint, problems, and computer codes (in the C language) all
serve to solicit reader involvement. An accompanying CD-ROM contains all source codes from the text as well as executable demo versions of commercial CAD codesv that illustrate use of the principles in the book. Intented for senior and/or graduate level students in electrical engineering or computer science, this book is suitable for software engineers, electronic design engineers, and electromagnetic research professionals in the field.
Tartalomjegyzék:
Part I. Transmission Line Fundamental
Chapter 1: Introduction
Fundamental Approach
Overview
The Transmission Line Partial Differentiual Equations (PDE's)
The Quasi-Static Approximation
Solution Methods for the Transmission Line Equations
Chapter 2: Single-Wire Lines
The Wave Equation
Lossless Line
Termination in the Characteristic Impedance zo
Termination with a Resistive Load
Time stepping Transmission line solutions
Numerical Algorithm - Propagation
Lossy Lines
Small Backward Signal Approximation
Numerical Algorithms - Lossy Propagation
Chapter 3: Solutions of Resistive Networks
Kirchoff's Laws
Voltage and Current Sources
Thevenin Equivalent Circuits
Norton Equivalent Circuits
General Network Solutions Using Norton Equivalent Circuits
Chapter 4: Boundary Conditions - Line End Equivalent Circuits
Thevenin Equivalent Circuits for a Transmission Line
Norton Equivalent Circuits for a Transmission Line
Joining Two or more Transmission Lines together
Chapter 5: Multi-Wire Lines - Single Propagation Speed
Propagation
Propagation Modes
Separation into Forward and Backward Signals
Lossless Line
Lossy Lines
Small Coupling Approximation of Propagation Crosstalk
Numerical Algorithms - Lossy Propagation with Crosstalk
Boudnary Conditions - Line End Equivalent Circuits
Thevenin Equivalent Circuit
Norton Equivalent Circuit
Reflection at a resistive termination
Termination Crosstalk Between Traces
Part II: Circuit Solutions at Line Terminations
Chapter 6: Networks with Reactive and Non-linear Elements
Networks of Resistors
Synthesis of a Symmetric resistive circuit matrix
Approximate Norton Equivalent for an two-terminal network
Norton Equivalent for a Capacitor
Norton Equivalent for an Inductor
Norton Equivalent for an AC termination
Performance of an AC Termination
Non-linear Two-terminal Circuit Elements
Chapter 7: Simultaneous Transmission Line Networeks Solutions
Multi-Wire Line Terminated in a network
Network of multi-wire lines and other Norton circuits
Chapter 8: Computer Algorithms for General network solutions
General Structure of the code
Data Input - network definition
Initializing the transmission lines
Initializing the networks
Open output files
Time-stepping Loop
Loading the Circuit Matrix G and Column Vector I
Solution of the network equations
Output Node voltages
Update Isc for Capacitors, Inductors and AC Termination
Update Transmission Lines
Closing the Output files
Chapter 9: Examples of Solutions Using Computer Code 8-1
Single-Wire Line - Various Terminations
Output for the Line with matching Load resistor
Output for the Line with a Non-Linear Load resistor
Line with AC termination
Three-Wire Line - Control of Crosstalk
Branched Traces
Part III. Propagation in Layered Media
Chapter 10: Modal Analysis in Layered Media
The Vector Wave Equations for Lossless Lines
Example of Multi-Speed Line
Propagation Modes of Multi-Speed Lines
Diagonalization of a Matrix
Chapter 11: Characteristic Impedance of Multi-Speed Lines
Impedance Matrix for a Single Mode
Impedance Matrix, Combined Modes
Impedance Matrix in the Modal Basis
Chapter 12: Transport on Lossy Multi-Speed Lines
Transmission Line Equations in the modal Basis
Transport Equations in the modal Basis
Transport Difference Approximation in the modal Basis
Chapter 13: Small Coupling Approximation of Propagation Crosstalk
Definition of the Primary Signal
The Secondary Signal, An Approximation of Propagation Crosstalk
Propagation Crosstalk of Impulse Function
Chapter 14: Networks Solutions Using Modal Analysis
Separating and Recombining the Propagation Modes
Solution of Networks with Multi-Speed Lines
Lossless Multi-Speed Lines
Lossy Multi-Speed Lines
Part IV: Transmission Line Parameter Determination
Chapter 15: Introduction to Transmission Line Parameter Determination
Chapter 16: Capacitance and Inductance in a Homogeneous Medium
Single Trace Capacitance and Inductance Simulation
Definition of Capacitance
The Capacitance of a single trace over a ground plane
Integral Equation for the charge
Potential and Electric Field of a Uniformly Charged Segment
Charged Segment near a Conducting Plane
Inductance Simulation
Calculated Results and their Accuracy
Multi-Trace Capacitance and Inductance Simulation
Definition of Capacitance matrix
Capacitance matrix Simulation
Inductance Simulation
Chapter 17: Electric Fields in Layered Circuit Board
Boundary Charge at a Dielectric-Dielectric Boundary
Equivalent Charge at Dielectric-Dielectric Boundaries
Dielectrics Adjacent to Trace Surfaces
Equivalent Charges Induced by Physical Charges
Dielectric Boundary Intersecting a Conducting Surface
Chapter 18: Calculation of Capacitance in a Layered Media
Chapter 19: Capacitance and Inductance Between Two Ground Planes
Potential due to a Uniformly Charged Segment
Electric Field due to Segment Parallel to the X Axis
Electric Field due to Segment Parallel to the Y Axis
Calculating the Capacitance and Inductance Matrices
Part V: Simulation of Skin effect
Chapter 20: Physics of the Skin Effect
Diffusion in a Slab
Classical Skin Effect
Chapter 21: Plane Geometry Skin Effect Simulation
D.C. Current Density and Magnetic Field
Diffusion Equation Solutions
Equivalent Circuit for Two-Sided Diffusion
Diffusion on One Side of a Slab
Algorithm for Diffusive Voltage Drop
Diffusive Response to a Current Ramp
Norton and Thevenin Equivalents for Diffusion
Convergence of the Slab-Diffusion Series
Chapter 22: Cylindrical Geometry Skin Effect Simulation
Field Partial Differential Equations
D.C. Current Density and Magnetic Field
Diffusion Equation Solutions
Equivalent Circuit for Diffusive Cylinder
Internal Inductance of a Cylindrical Conductor
Norton Equivalent Circuit for a Diffusive Cylinder
Chapter 23: Propagation with Skin effect
Distributed Voltage Source in the Transmission Line Equations
Lossy propagation with Diffusion
Modified Circular Array for propagation with Diffusion
Approximations Using Lumped Element Diffusion Model
Appendices
Appendix A: Equivalence of Time-Domain and Frequency Domain Methods
Appendix B: Effect of Resistance in Reference Conductor
Solutions of Problems
References
