Radio-Frequency Integrated-Circuit Engineering

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Informationen zum Autor Cam Nguyen, PhD, IEEE Fellow, is the Texas Instruments Endowed Professor of Electrical and Computer Engineering at Texas A&M University. He was Program Director at the National Science Foundation during 2003-2004, responsible for research programs in RF and wireless technologies. Over the past 35 years, including 12 years at TRW, Martin Marietta, Aeroject ElectroSystems, Hughes Aircraft and ITT Gilfillan, Professor Nguyen has led numerous RF projects for wireless communications, radar and sensing; developed many RF integrated circuits and systems up to 220 GHz; published five books, six book chapters, over 255 papers; and given more than 160 conference presentations. Klappentext Die Technologie komplementärer Metalloxid-Halbleiter (Complementary Metal-Oxide Semiconductor, CMOS) kommt bei der Fertigung integrierter Schaltkreise zum Einsatz. In diesem Fachbuch werden Theorie, Analyse, Eigenschaften (Hochfrequenz/Hochgeschwindigkeit) und Anwendungen von Leiterplatten-Übertragungsleitungen, die in integrierten Schaltkreisen und Systemen verwendet werden, ausführlich behandelt. Weitere Themen sind Anwendungen in allen Bereichen der Hochfrequenztechnik, einschließlich drahtlose Kommunikation, Optik und Computer. Das Fachbuch ist durch das Lösungshandbuch ideal für Studenten im höheren Grundstudium, Ingenieure für Hochfrequenz-Mikrowellentechnik, Optikingenieure, Ingenieure für Festkörperbauelemente und für Computeringenieure. Zusammenfassung Complementary metal-oxide-semiconductor (CMOS) is a technology for constructing integrated circuits. This book thoroughly discusses the theory, analysis, design, and high-frequency/high-speed characteristics and applications of printed-circuit transmission lines used in integrated circuits and systems. Inhaltsverzeichnis Preface xvii 1 Introduction 1 Problems 5 2 Fundamentals of Electromagnetics 6 2.1 EM Field Parameters 6 2.2 Maxwell's Equations 7 2.3 Auxiliary Relations 8 2.3.1 Constitutive Relations 8 2.3.2 Current Relations 9 2.4 Sinusoidal Time-Varying Steady State 9 2.5 Boundary Conditions 10 2.5.1 General Boundary Conditions 11 2.5.2 Specific Boundary Conditions 11 2.6 Wave Equations 12 2.7 Power 13 2.8 Loss and Propagation Constant in Medium 14 2.9 Skin Depth 16 2.10 Surface Impedance 17 Problems 19 3 Lumped Elements 20 3.1 Fundamentals of Lumped Elements 20 3.1.1 Basic Equations 23 3.2 Quality Factor of Lumped Elements 28 3.3 Modeling of Lumped Elements 30 3.4 Inductors 32 3.4.1 Inductor Configurations 32 3.4.2 Loss in Inductors 36 3.4.3 Equivalent-Circuit Models of Inductors 39 3.4.4 Resonance in Inductors 45 3.4.5 Quality Factor of Inductors 46 3.4.6 High Q Inductor Design Considerations 51 3.5 Lumped-Element Capacitors 60 3.5.1 Capacitor Configurations 60 3.5.2 Equivalent-Circuit Models of Capacitors 63 3.5.3 Resonance 68 3.5.4 Quality Factor 69 3.5.5 High Q Capacitor Design Considerations 71 3.6 Lumped-Element Resistors 72 3.6.1 Resistor Configurations 72 3.6.2 Basic Resistor Equations 72 3.6.3 Equivalent-Circuit Models of Resistors 75 References 75 Problems 76 4 Transmission Lines 85 4.1 Essentials of Transmission Lines 85 4.2 Transmission-Line Equations 86 4.2.1 General Transmission-Line Equations 86 4.2.2 Sinusoidal Steady-State Transmission-Line Equations 91 4.3 Transmission-Line Parameters 93 4.3.1 General Transmission Lines 93 4.3.2 Lossless Transmission Lines 96 4.3.3 Low Loss Transmission Lines 96 4.4 Per-Unit-Length Parameters R,L,C, and G 97 4.4.1 General Formulation 97 4.4....

List of contents

PREFACE xvii
 
1 INTRODUCTION 1
 
Problems 5
 
2 FUNDAMENTALS OF ELECTROMAGNETICS 6
 
2.1 EM Field Parameters 6
 
2.2 Maxwell's Equations 7
 
2.3 Auxiliary Relations 8
 
2.4 Sinusoidal Time-Varying Steady State 9
 
2.5 Boundary Conditions 10
 
2.6 Wave Equations 12
 
2.7 Power 13
 
2.8 Loss and Propagation Constant in Medium 14
 
2.9 Skin Depth 16
 
2.10 Surface Impedance 17
 
Problems 19
 
3 LUMPED ELEMENTS 20
 
3.1 Fundamentals of Lumped Elements 20
 
3.2 Quality Factor of Lumped Elements 28
 
3.3 Modeling of Lumped Elements 30
 
3.4 Inductors 32
 
3.5 Lumped-Element Capacitors 60
 
3.6 Lumped-Element Resistors 72
 
References 75
 
Problems 76
 
4 TRANSMISSION LINES 85
 
4.1 Essentials of Transmission Lines 85
 
4.2 Transmission-Line Equations 86
 
4.3 Transmission-Line Parameters 93
 
4.4 Per-Unit-Length Parameters R,L,C, and G 97
 
4.5 Dielectric and Conductor Losses in Transmission Lines 107
 
4.6 Dispersion and Distortion in Transmission Lines 111
 
4.7 Group Velocity 115
 
4.8 Impedance, Reflection Coefficients, and Standing-Wave Ratios 117
 
4.9 Synthetic Transmission Lines 126
 
4.10 Tem and Quasi-Tem Transmission-Line Parameters 128
 
4.11 Printed-Circuit Transmission Lines 132
 
4.12 Transmission Lines in RFICs 144
 
4.13 Multi-Conductor Transmission Lines 152
 
References 173
 
Problems 174
 
Appendix 4: Transmission-Line Equations Derived From Maxwell's Equations 182
 
5 RESONATORS 186
 
5.1 Fundamentals of Resonators 186
 
5.2 Quality Factor 189
 
5.3 Distributed Resonators 205
 
5.4 Resonator's Slope Parameters 231
 
5.5 Transformation of Resonators 231
 
References 237
 
Problems 238
 
6 IMPEDANCE MATCHING 244
 
6.1 Basic Impedance Matching 244
 
6.2 Design of Impedance-Matching Networks 248
 
6.3 Kuroda Identities 262
 
References 266
 
Problems 266
 
7 SCATTERING PARAMETERS 271
 
7.1 Multiport Networks 271
 
7.2 Impedance Matrix 273
 
7.3 Admittance Matrix 274
 
7.4 Impedance and Admittance Matrix in RF Circuit Analysis 274
 
7.5 Scattering Matrix 279
 
7.6 Chain Matrix 293
 
7.7 Scattering Transmission Matrix 294
 
7.8 Conversion Between Two-Port Parameters 295
 
References 298
 
Problems 298
 
8 RF PASSIVE COMPONENTS 304
 
8.1 Characteristics of Multiport RF Passive Components 304
 
8.2 Directional Couplers 311
 
8.3 Hybrids 326
 
8.4 Power Dividers 339
 
8.5 Filters 345
 
References 371
 
Problems 372
 
9 FUNDAMENTALS OF CMOS TRANSISTORS FOR RFIC DESIGN 379
 
9.1 MOSFET Basics 379
 
9.2 MOSFET Models 386
 
9.3 Important MOSFET Frquencies 407
 
9.4 Other Important MOSFET Parameters 409
 
9.5 Varactor Diodes 409
 
References 412
 
Problems 412
 
10 STABILITY 418
 
10.1 Fundamentals of Stability 418
 
10.2 Determination of Stable and Unstable Regions 421
 
10.3 Stability Consideration for N-Port Circuits 427
 
References 427
 
Problems 428
 
11 AMPLIFIERS 430
 
11.1 Fundamentals of Amplifier Design 430
 
11.2 Low Noise Amplifiers 443
 
11.3 Design Examples 451
 
11.4 Power Amplifiers 455
 
11.5 Balanced Am