Analysis of Multiconductor Transmission LinesThe essential textbook for electrical engineering students and professionals-now in a valuable new edition The increasing use of high-speed digital technology requires that all electrical engineers have a working knowledge of transmission lines. However, because of the introduction of computer engineering courses into already-crowded four-year undergraduate programs, the transmission line courses in many electrical engineering programs have been relegated to a senior technical elective, if offered at all. Now, Analysis of Multiconductor Transmission Lines, Second Edition has been significantly updated and reorganized to fill the need for a structured course on transmission lines in a senior undergraduate- or graduate-level electrical engineering program. In this new edition, each broad analysis topic, e.g., per-unit-length parameters, frequency-domain analysis, time-domain analysis, and incident field excitation, now has a chapter concerning two-conductor lines followed immediately by a chapter on MTLs for that topic. This enables instructors to emphasize two-conductor lines or MTLs or both. In addition to the reorganization of the material, this Second Edition now contains important advancements in analysis methods that have developed since the previous edition, such as methods for achieving signal integrity (SI) in high-speed digital interconnects, the finite-difference, time-domain (FDTD) solution methods, and the time-domain to frequency-domain transformation (TDFD) method. Furthermore, the content of Chapters 8 and 9 on digital signal propagation and signal integrity application has been considerably expanded upon to reflect all of the vital information current and future designers of high-speed digital systems need to know. |
From inside the book
Results 1-5 of 86
Page x
... Approximation 260 6.4 Lumped-Circuit Approximate Models of the Line 265 6.5 Alternative Two-Port Representations of the Line 269 6.5.1 The Chain Parameters 270 6.5.2 Approximating Abruptly Nonuniform Lines with the Chain-Parameter ...
... Approximation 260 6.4 Lumped-Circuit Approximate Models of the Line 265 6.5 Alternative Two-Port Representations of the Line 269 6.5.1 The Chain Parameters 270 6.5.2 Approximating Abruptly Nonuniform Lines with the Chain-Parameter ...
Page xi
... Approximate Characterizations 312 7.5 Alternative 2n - Port Characterizations 314 7.5.1 Analogy of the Frequency - Domain MTL Equations to State - Variable Equations 314 7.5.2 Characterizing the Line as a 2n - Port with the Chain ...
... Approximate Characterizations 312 7.5 Alternative 2n - Port Characterizations 314 7.5.1 Analogy of the Frequency - Domain MTL Equations to State - Variable Equations 314 7.5.2 Characterizing the Line as a 2n - Port with the Chain ...
Page xii
... Approximate Characterizations 8.2.5 The Use of Macromodels in Modeling the Line 8.2.6 Representing Frequency-Dependent Functions in the Time Domain Using Pade Methods 439 443 447 450 453 Problems 461 References 467 9.1 9 Time-Domain ...
... Approximate Characterizations 8.2.5 The Use of Macromodels in Modeling the Line 8.2.6 Representing Frequency-Dependent Functions in the Time Domain Using Pade Methods 439 443 447 450 453 Problems 461 References 467 9.1 9 Time-Domain ...
Page xiii
Clayton R. Paul. CONTENTS xiii 9.2.2 Lumped - Circuit Approximate Characterizations 9.2.3 The Finite - Difference ... Approximation of the Matrix Exponential 9.2.5.2 Asymptotic Waveform Evaluation ( AWE ) 9.2.5.3 Complex Frequency Hopping ...
Clayton R. Paul. CONTENTS xiii 9.2.2 Lumped - Circuit Approximate Characterizations 9.2.3 The Finite - Difference ... Approximation of the Matrix Exponential 9.2.5.2 Asymptotic Waveform Evaluation ( AWE ) 9.2.5.3 Complex Frequency Hopping ...
Page xiv
... Approximate Characterizations 12.2.5 Uniform Plane - Wave Excitation of the Line 660 660 12.3 The Time - Domain Solution 667 12.3.1 Decoupling the MTL Equations 668 12.3.2 A SPICE Equivalent Circuit 674 12.3.3 Lumped - Circuit Approximate ...
... Approximate Characterizations 12.2.5 Uniform Plane - Wave Excitation of the Line 660 660 12.3 The Time - Domain Solution 667 12.3.1 Decoupling the MTL Equations 668 12.3.2 A SPICE Equivalent Circuit 674 12.3.3 Lumped - Circuit Approximate ...
Contents
Introduction | 1 |
43 | 22 |
56 | 28 |
Problems | 61 |
References | 69 |
77 | 137 |
79 | 156 |
Rectangular Cross Section | 189 |
References | 399 |
Problems | 461 |
References | 467 |
Terminations in the FDTD Analysis | 490 |
Literal Symbolic Solutions for ThreeConductor Lines | 544 |
Problems | 575 |
CONTENTS | 592 |
Problems | 638 |
81 | 208 |
The TransmissionLine Equations for Multiconductor Lines | 215 |
FrequencyDomain Analysis of TwoConductor Lines | 240 |
1 | 260 |
Problems | 278 |
Problems | 338 |
Equations from the Integral Form of Maxwells Equations | 386 |
Common terms and phrases
ANALYSIS OF MULTICONDUCTOR approximate bound charge capacitance matrix chain-parameter matrix Chapter characteristic impedance charge distribution computed cross section crosstalk denoted determine diagonal dielectric domain electric field Electromagnetic Compatibility FDTD frequency frequency-domain FREQUENCY-DOMAIN ANALYSIS gives ground plane Hence homogeneous medium identical IEEE Transactions illustrated in Figure INCIDENT FIELD EXCITATION inhomogeneous input internal inductance ith conductor Laplace transform line length line voltages load voltage losses lossless line lossy lumped-Pi method mils MTL equations MULTICONDUCTOR LINES multiconductor transmission lines near-end crosstalk node obtained per-unit-length capacitance per-unit-length inductance PER-UNIT-LENGTH PARAMETERS permittivity pF/m phasor potential predictions printed circuit board propagation pulse reference conductor reflection coefficient resistance ribbon cable shown in Figure skin effect solution solved SPICE model Substituting surface TDFD time-domain transmission lines transmission-line equations transverse TWO-CONDUCTOR LINES vector voltages and currents Vs(t wave waveform wire zero