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发表于 2024-8-16 11:13:05
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Table of Contents
Cover
Title Page
Copyright
List of Trademarks
Dedication
Preface
Acknowledgements
Chapter 1: Introduction to Design Using Microstrip and Planar Lines
1.1 Introduction
1.2 Origins of Microstrip
1.3 RF and Microwave Modules
1.4 Interconnections on RF and Microwave Integrated Circuits
1.5 High-speed Digital Interconnections
1.6 Summary
References
Chapter 2: Fundamentals of Signal Transmission on Interconnects
2.1 Introduction
2.2 Transmission Lines and Interconnects
2.3 Interconnects as Part of a Packaging Hierarchy
2.4 The Physical Basis of Interconnects
2.5 The Physics, a Guided Wave
2.6 When an Interconnect Should be Treated as a Transmission Line
2.7 The Concept of RF Transmission Lines
2.8 Primary Transmission Line Constants
2.9 Secondary Constants for Transmission Lines
2.10 Transmission Line Impedances
2.11 Reflection
2.12 Multiple Conductors
2.13 Return Currents
2.14 Modeling of Interconnects
2.15 Summary
References
Chapter 3: Microwave Network Analysis
3.1 Introduction
3.2 Two-port Networks
3.3 Scattering Parameter Theory
3.4 Signal-flow Graph Techniques and Parameters
3.5 Summary
References
Chapter 4: Transmission Line Theory
4.1 Introduction
4.2 Transmission Line Theory
4.3 Chain (ABCD) Parameters for a Uniform Length of Loss-free Transmission Line
4.4 Change in Reference Plane
4.5 Working With a Complex Characteristic Impedance
4.6 Summary
References
Chapter 5: Planar Interconnect Technologies
5.1 Introductory Remarks
5.2 Microwave Frequencies and Applications
5.3 Transmission Line Structures
5.4 Substrates for Planar Transmission Lines
5.5 Thin-film Modules
5.6 Thick-film Modules
5.7 Monolithic Technology
5.8 Printed Circuit Boards
5.9 Multichip Modules
5.10 Summary
References
Chapter 6: Microstrip Design at Low Frequencies
6.1 The Microstrip Design Problem
6.2 The Quasi-TEM Mode of Propagation
6.3 Static-TEM Parameters
6.4 Effective Permittivity and Characteristic Impedance of Microstrip
6.5 Filling Factor
6.6 Approximate Graphically Based Synthesis
6.7 Formulas for Accurate Static-TEM Design Calculations
6.8 Electromagnetic Analysis-based Techniques
6.9 A Worked Example of Static-TEM Synthesis
6.10 Microstrip on a Dielectrically Anisotropic Substrate
6.11 Microstrip and Magnetic Materials
6.12 Effects of Finite Strip Thickness, Metallic Enclosure, and Manufacturing
Tolerances
6.13 Pulse Propagation along Microstrip Lines
6.14 Recommendations Relating to the Static-TEM Approaches
6.15 Summary
References
Chapter 7: Microstrip at High Frequencies
7.1 Introduction
7.2 Frequency-dependent Effects
7.3 Approximate Calculations Accounting for Dispersion
7.4 Accurate Design Formulas
7.5 Effects due to Ferrite and to Dielectrically Anisotropic Substrates
7.6 Field Solutions
7.7 Frequency Dependence of Microstrip Characteristic Impedance
7.8 Multimoding and Limitations on Operating Frequency
7.9 Design Recommendations
7.10 Summary
References
Chapter 8: Loss and Power-dependent Effects in Microstrip
8.1 Introduction
8.2 Factor as a Measure of Loss
8.3 Power Losses and Parasitic Effects
8.4 Superconducting Microstrip Lines
8.5 Power-handling Capabilities
8.6 Passive Intermodulation Distortion
8.7 Summary
References
Chapter 9: Discontinuities in Microstrip
9.1 Introduction
9.2 The Main Discontinuities
9.3 Bends in Microstrip
9.4 Step Changes in Width (Impedance Step)
9.5 The Narrow Transverse Slit
9.6 Microstrip Junctions
9.7 Recommendations for the Calculation of Discontinuities
9.8 Summary
References
Chapter 10: Parallel-coupled Microstrip Lines
10.1 Introduction
10.2 Coupled Transmission Line Theory
10.3 Formulas for Characteristic Impedance of Coupled Lines
10.4 Semi-empirical Analysis Formulas as a Design Aid
10.5 An Approximate Synthesis Technique
10.6 Summary
References
Chapter 11: Applications of Parallel-coupled Microstrip Lines
11.1 Introduction
11.2 Directional Couplers
11.3 Design Example: Design of a 10 dB Microstrip Coupler
11.4 Frequency- and Length-Dependent Characteristics of Directional Couplers
11.5 Special Coupler Designs with Improved Performance
11.6 Thickness Effects, Power Losses, and Fabrication Tolerances
11.7 Choice of Structure and Design Recommendations
11.8 Summary
References
Chapter 12: Microstrip Passive Elements
12.1 Introduction
12.2 Lumped Elements
12.3 Terminations and Attenuators
12.4 Microstrip Stubs
12.5 Hybrids and Couplers
12.6 Power Combiners and Dividers
12.7 Baluns
12.8 Integrated Components
12.9 Summary
References
Chapter 13: Stripline Design
13.1 Introduction
13.2 Symmetrical Stripline
13.3 Asymmetrical Stripline
13.4 Suspended Stripline
13.5 Coupled Stripline
13.6 Double-sided Stripline
13.7 Discontinuities
13.8 Design Recommendations
13.9 Summary
References
Chapter 14: CPW Design Fundamentals
14.1 Introduction to Properties of Coplanar Waveguide
14.2 Modeling CPWs
14.3 Formulas for Accurate Calculations
14.4 Loss Mechanisms
14.5 Dispersion
14.6 Discontinuities
14.7 Circuit Elements
14.8 Variants on the Basic CPW Structure
14.9 Summary
References
Chapter 15: Slotline
15.1 Introduction
15.2 Basic Concept and Structure
15.3 Operating Principles and Modes
15.4 Propagation and Dispersion Characteristics
15.5 Evaluation of Guide Wavelength and Characteristic Impedance
15.6 Losses
15.7 End-effects: Open Circuits and Short Circuits
15.8 Summary
References
Chapter 16: Slotline Applications
16.1 Introduction
16.2 Comparators and Couplers
16.3 Filter Applications
16.4 Magic T
16.5 The Marchand Balun
16.6 Phase Shifters
16.7 Isolators and Circulators
16.8 A Double-sided, Balanced Microwave Circuit
16.9 Summary
References
Chapter 17: Transitions
17.1 Introduction
17.2 Coaxial-to-microstrip Transitions
17.3 Waveguide-to-microstrip Transitions
17.4 Transitions between CPW and other Mediums
17.5 Slotline Transitions
17.6 Other Microstrip Transitions
17.7 Summary
References
Chapter 18: Measurements of Planar Transmission Line Structures
18.1 Introduction
18.2 Instrumentation Systems for Microstrip Measurements
18.3 Measurement of Scattering Parameters
18.4 Measurement of Substrate Properties
18.5 Microstrip Resonator Methods
18.6 Factor Measurements
18.7 Measurements of Parallel-coupled Microstrips
18.8 Time-domain Reflectometry Techniques
18.9 Summary
References
Chapter 19: Filters Using Planar Transmission Lines
19.1 Introduction
19.2 Filter Prototypes
19.3 Microstrip Filters
19.4 Microstrip Bandpass Filters
19.5 Parallel-coupled Line Bandpass Filters
19.6 Filter Design Accounting for Losses
19.7 Dielectric Resonators and Filters Using Them
19.8 Spurline Bandstop Filters
19.9 Summary
References
Chapter 20: Magnetic Materials and Planar Transmission Lines
20.1 Introduction
20.2 Microwave Magnetic Materials
20.3 Effective Permeability of Magnetic Materials
20.4 Microstrip on a Ferrite Substrate
20.5 Isolators and Circulators
20.6 Transmission Lines Using Metaconductors
20.7 Frequency Selective Limiter
20.8 Summary
References
Chapter 21: Interconnects for Digital Systems
21.1 Introduction
21.2 Overview of On-chip Interconnects
21.3 Modeling of On-chip Interconnects
21.4 Modeling Inductance
21.5 Clock Distribution
21.6 Resonant Clock Distribution
21.7 Summary
References
Appendix A: Physical and Mathematical Prop |
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