Synopses & Reviews
High frequencies of densely packed modern electronic equipment turn even the smallest piece of wire into a transmission line with signal retardation, dispersion, attenuation, and distortion. In electromagnetic environments with high-power microwave or ultra-wideband sources, transmission lines pick up noise currents generated by external electromagnetic fields. These are superimposed on essential signals, the lines acting not only as receiving antennas but radiating parts of the signal energy into the environment.
This book is outstanding in its originality. While many textbooks rephrase that which has been written before, this book features:
- an accessible introduction to the fundamentals of electromagnetics;
- an explanation of the newest developments in transmission line theory, featuring the transmission line super theory developed by the authors;
- a unique exposition of the increasingly popular PEEC (partial element equivalent circuit) method, including recent research results.
Both the Transmission Line Theory and the PEEC method are well suited to combine linear structures with circuit networks.
For engineers, researchers, and graduate students, this text broadens insight into the basics of electrical engineering. It provides a deeper understanding of Maxwellian-circuit-like representations of multi-conductor transmission lines, justifies future research in this field.
Synopsis
High speed, high frequency communications generate increased radiation levels, and practical solutions to this problem are in heavy demand. At the research level, classical EMC theory has been extended to non-parallel transmission lines addressing the increased radiation emitted at high frequency transmissions. Transmissions from antennae in the region of GHz can result in EM interference with aircraft electronic circuitry and potentially pose a health risk to humans. EMC and Non-uniform Transmission Lines will provide comprehensive coverage of both classical and non-parallel transmission line theory, surveying the most up-to-date research and current thinking in the field. The scope also spans EMC topology, used to describe very complex systems by analysing the EM interactions between the various components.
Synopsis
Durch immer schnellere bertragungsgeschwindigkeiten sind Leitungen immer anf lliger gegen elektromagnetische Unvertr glichkeit und St rungen durch Abstrahlungseinfl sse. Mit der Erforschung von nicht-paralleler Leitungsanordnungen soll dies der Vergangenheit angeh ren.
Table of Contents
Preface.References.
Acknowledgments.
List of Symbols.
Introduction.
1 Fundamentals of Electrodynamics.
1.1 Maxwell Equations Derived from Conservation Laws – an Axiomatic Approach.
1.2 The Electromagnetic Field as a Gauge Field – a Gauge Field Approach.
1.3 The Relation Between the Axiomatic Approach and the Gauge Field Approach.
1.4 Solutions of Maxwell Equations.
1.5 Boundary Value Problems and Integral Equations.
References.
2 Nonuniform Transmission-Line Systems.
2.1 Multiconductor Transmission Lines: General Equations.
2.2 General Calculation Methods for the Product Integral/Matrizant.
2.3 Semi-Analytic and Numerical Solutions for Selected Transmission Lines in the TLST.
2.4 Analytic Approaches.
References.
3 Complex Systems and Electromagnetic Topology.
3.1 The Concept of Electromagnetic Topology.
3.2 Topological Networks and BLT Equations.
3.3 Transmission Lines and Topological Networks.
3.4 Shielding.
References.
4 The Method of Partial Element Equivalent Circuits (PEEC Method).
4.1 Fundamental Equations.
4.2 Derivation of the Generalized PEEC Method in the Frequency Domain.
4.3 Classification of PEEC Models.
4.4 PEEC Models for the Plane Half Space.
4.5 Geometrical Discretization in PEEC Modeling.
4.6 PEEC Models for the Time Domain and the Stability Issue.
4.7 Skin Effect in PEEC Models.
4.8 PEEC Models Based on Dyadic Green’s Functions for Conducting Structures in Layered Media.
4.9 PEEC Models and Uniform Transmission Lines.
4.10 Power Considerations in PEEC Models.
References.
Appendix A: Tensor Analysis, Integration and Lie Derivative.
A.1 Integration Over a Curve and Covariant Vectors as Line Integrands.
A.2 Integration Over a Surface and Contravariant Vector Densities as Surface Integrands.
A.3 Integration Over a Volume and Scalar Densities as Volume Integrands.
A.4 Poincaré Lemma.
A.5 Stokes’ Theorem.
A.6 Lie Derivative.
References.
Appendix B: Elements of Functional Analysis.
B.1 Function Spaces.
B.2 Linear Operators.
B.3 Spectrum of a Linear Operator.
B.4 Spectral Expansions and Representations.
References.
Appendix C: Some Formulas of Vector and Dyadic Calculus.
C.1 Vector Identities.
C.2 Dyadic Identities.
C.3 Integral Identities.
Reference.
Appendix D: Adaption of the Integral Equations to the Conductor Geometry.
Appendix E: The Product Integral/Matrizant.
E.1 The Differential Equation and Its Solution.
E.2 The Determination of the Product Integral.
E.3 Inverse Operation.
E.4 Calculation Rules for the Product Integral.
References.
Appendix F: Solutions for Some Important Integrals.
F.1 Integrals Involving Powers of √x2 + b2.
F.2 Integrals Involving Exponential and Power Functions.
F.3 Integrals Involving Trigonometric and Exponential Functions.
Reference.
Index.