San Diego, : Academic Press, c2001

1-281-05895-5

9786611058951

0-08-051959-8

1 online resource (503 p.)

Electromagnetism

Academic press series in electromagnetism

MaffucciAntonio

621.319

Electric lines

Electric networks

Electronic circuits

Electric circuit analysis - Mathematics

Inglese

Description based upon print version of record.

Includes bibliographical references (p. 463-470) and index.

Front Cover; Transmission Lines and Lumped Circuits; Copyright Page; Contents; Foreword; Preface; Introduction; Chapter 1. Transmission Line Equations and Properties; 1.1 Transmission Line Model; 1.2 Two-Conductor Transmission Line Equations; 1.3 Multiconductor Transmission Line Equations; 1.4 Poynting's Theorem for Lines with Frequency Independent Parameters; 1.5 Uniqueness of the Solution of Transmission Line Equations; 1.6 Poynting's Theorem for Lines in the Frequency Domain; 1.7 Uniqueness of the Solution of Transmission Line Equations with Frequency-Dependent Parameters

1.8 Transmission Line Equations in the Laplacde Domain1.9 Reciprocity Theorems for Two-Conductor Transmission Lines; 1.10 Reciprocity Theorems for Multiconductor Transmission Lines; Chapter 2. Ideal Two-Conductor Transmission Lines Connected to Lumped Circuits; 2.1 d'Alembert Solution of Two-Conductor Transmission Line Equations; 2.2 Some Elementary Networks; 2.3 Natural Frequencies of a Finite Length Transmission Line Connected to Short Circuits; 2.4 Two-Conductor Transmission Lines as Two-Ports; 2.5 The Input-Output

Description

2.6 The Input-State-Output Description, and Equivalent Circuits of Thévenin and Norton Type2.7 Lines Connected to Linear Lumped Circuits; 2.8 A Glimpse at a Transmission Line Connected to a Nonlinear One-Port: State Equations in Normal Form; 2.9 Ideal Two-Conductor Transmission Lines with Distributed Sources; Chapter 3. Ideal Multiconductor Transmission Lines; 3.1 d'Alembert Solution for Ideal Multiconductor Transmission Lines; 3.2 Infinite Multiconductor Transmission Lines; 3.3 Semi-infinite Multiconductor Transmission Lines and Equivalent Circuits

3.4 Ideal Multiconductor Transmission Lines asMultiports3.5 The Input-State-Output Description and the Equivalent Circuits of Thévenin and Norton Type; 3.6 Multiconductor Lines with Homogeneous Dielectric; 3.7 Multiconductor Transmission Line Connected to Linear Resistive Multiports; 3.8 A Particular Solution of the Ideal Multiconductor Transmission Line Equations with Distributed Sources; 3.9 Properties of the Characteristic Conductance Matrix Gc and Resistance Matrix Rc; Chapter 4. Lossy Two-Conductor Transmission Lines; 4.1 Lossy Transmission Lines are Dispersive

4.2 Solution of the Lossy Transmission Line Equations in the Laplace Domain4.3 The Propagation Along a Lossy Transmission Line; 4.4 Semi-infinite Lossy Line Connected to an Ideal Current Source; 4.5 Representation of Lossy Two-Conductor Lines as Two-Ports; 4.6 The Input-State-Output Description; 4.7 Input-Output Descriptions in Explicit Form; 4.8 A Lossy Transmission Line Connecting Two Linear Resistive One-Ports; 4.9 The Matching Problem for Lossy Lines; 4.10 Lossy Transmission Lines with Distributed Sources

4.11 Characterization of the Terminal Behavior of the Line Through the Scattering Parameters

The theory of transmission lines is a classical topic of electrical engineering.  Recently this topic has received renewed attention and has been a focus of considerable research.  This is because the transmisson line theory has found new and important applications in the area of high-speed VLSI interconnects, while it has retained its significance in the area of power transmission.  In many applications, transmission lines are connected to nonlinear circuits.  For instance, interconnects of high-speed VLSI chips can be modelled as transmission lines loaded with nonlinear elements.  These nonl