Radio Frequency Circuit Design, 2nd Edition

Author W. Alan Davis

Release Date: 2010/12/01

ISBN: 9781118099476

Topic:

Math, Science, Engineering

28
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Book Description

This book focuses on components such as filters, transformers, amplifiers, mixers, and oscillators. Even the phase lock loop chapter (the last in the book) is oriented toward practical circuit design, in contrast to the more systems orientation of most communication texts.

Cover
Title page
Copyright page
Dedication
Preface to the Second Edition
Preface to the First Edition
CHAPTER ONE Information Transfer Technology
1. 1.1 INTRODUCTION
2. 1.2 INFORMATION AND CAPACITY
3. 1.3 DEPENDENT STATES
4. 1.4 BASIC TRANSMITTER–RECEIVER CONFIGURATION
5. 1.5 ACTIVE DEVICE TECHNOLOGY
CHAPTER TWO Resistors, Capacitors, and Inductors
1. 2.1 INTRODUCTION
2. 2.2 RESISTORS
3. 2.3 CAPACITORS
4. 2.4 INDUCTORS
5. 2.5 CONCLUSIONS
CHAPTER THREE Impedance Matching
1. 3.1 INTRODUCTION
2. 3.2 THE Q FACTOR
3. 3.3 RESONANCE AND BANDWIDTH
4. 3.4 UNLOADED Q
5. 3.5 L CIRCUIT IMPEDANCE MATCHING
6. 3.6 π TRANSFORMATION CIRCUIT
7. 3.7 T TRANSFORMATION CIRCUIT
8. 3.8 TAPPED CAPACITOR TRANSFORMER
9. 3.9 PARALLEL DOUBLE-TUNED TRANSFORMER
10. 3.10 CONCLUSIONS
CHAPTER FOUR Multiport Circuit Parameters and Transmission Lines
1. 4.1 VOLTAGE–CURRENT TWO-PORT PARAMETERS
2. 4.2 ABCD PARAMETERS
3. 4.3 IMAGE IMPEDANCE
4. 4.4 TELEGRAPHER’S EQUATIONS
5. 4.5 TRANSMISSION LINE EQUATION
6. 4.6 SMITH CHART
7. 4.7 TRANSMISSION LINE STUB TRANSFORMER
8. 4.8 COMMONLY USED TRANSMISSION LINES
9. 4.9 SCATTERING PARAMETERS
10. 4.10 INDEFINITE ADMITTANCE MATRIX
11. 4.11 INDEFINITE SCATTERING MATRIX
12. 4.12 CONCLUSIONS
CHAPTER FIVE Filter Design and Approximation
1. 5.1 INTRODUCTION
2. 5.2 IDEAL AND APPROXIMATE FILTER TYPES
3. 5.3 TRANSFER FUNCTION AND BASIC FILTER CONCEPTS
4. 5.4 LADDER NETWORK FILTERS
5. 5.5 ELLIPTIC FILTER
6. 5.6 MATCHING BETWEEN UNEQUAL RESISTANCE LEVELS
7. 5.7 CONCLUSIONS
CHAPTER SIX Transmission Line Transformers
1. 6.1 INTRODUCTION
2. 6.2 IDEAL TRANSMISSION LINE TRANSFORMERS
3. 6.3 TRANSMISSION LINE TRANSFORMER SYNTHESIS
4. 6.4 ELECTRICALLY LONG TRANSMISSION LINE TRANSFORMERS
5. 6.5 BALUNS
6. 6.6 DIVIDERS AND COMBINERS
7. 6.7 THE 90 ° COUPLER
CHAPTER SEVEN Noise in RF Amplifiers
1. 7.1 SOURCES OF NOISE
2. 7.2 THERMAL NOISE
3. 7.3 SHOT NOISE
4. 7.4 NOISE CIRCUIT ANALYSIS
5. 7.5 AMPLIFIER NOISE CHARACTERIZATION
6. 7.6 NOISE MEASUREMENT
7. 7.7 NOISY TWO-PORT CIRCUITS
8. 7.8 TWO-PORT NOISE FACTOR DERIVATION
9. 7.9 FUKUI NOISE MODEL FOR TRANSISTORS
CHAPTER EIGHT Class A Amplifiers
1. 8.1 INTRODUCTION
2. 8.2 DEFINITION OF GAIN [2]
3. 8.3 TRANSDUCER POWER GAIN OF A TWO-PORT NETWORK
4. 8.4 TRANSDUCER POWER GAIN USING S PARAMETERS
5. 8.5 SIMULTANEOUS MATCH FOR MAXIMUM POWER GAIN
6. 8.6 STABILITY
7. 8.7 CLASS A POWER AMPLIFIERS
8. 8.8 POWER COMBINING OF POWER AMPLIFIERS
9. 8.9 PROPERTIES OF CASCADED AMPLIFIERS
10. 8.10 AMPLIFIER DESIGN FOR OPTIMUM GAIN AND NOISE
11. 8.11 CONCLUSION
CHAPTER NINE RF Power Amplifiers
1. 9.1 TRANSISTOR CONFIGURATIONS
2. 9.2 CLASS B AMPLIFIER
3. 9.3 CLASS C AMPLIFIER
4. 9.4 CLASS C INPUT BIAS VOLTAGE
5. 9.5 CLASS D POWER AMPLIFIER
6. 9.6 CLASS E POWER AMPLIFIER
7. 9.7 CLASS F POWER AMPLIFIER
8. 9.8 FEED-FORWARD AMPLIFIERS
9. 9.9 CONCLUSIONS
CHAPTER TEN Oscillators and Harmonic Generators
1. 10.1 OSCILLATOR FUNDAMENTALS
2. 10.2 FEEDBACK THEORY
3. 10.3 TWO-PORT OSCILLATORS WITH EXTERNAL FEEDBACK
4. 10.4 PRACTICAL OSCILLATOR EXAMPLE
5. 10.5 MINIMUM REQUIREMENTS OF THE REFLECTION COEFFICIENT
6. 10.6 COMMON GATE (BASE) OSCILLATORS
7. 10.7 STABILITY OF AN OSCILLATOR
8. 10.8 INJECTION-LOCKED OSCILLATORS
9. 10.9 OSCILLATOR PHASE NOISE
10. 10.10 HARMONIC GENERATORS
CHAPTER ELEVEN RF Mixers
1. 11.1 NONLINEAR DEVICE CHARACTERISTICS
2. 11.2 FIGURES OF MERIT FOR MIXERS
3. 11.3 SINGLE-ENDED MIXERS
4. 11.4 SINGLE-BALANCED MIXERS
5. 11.5 DOUBLE-BALANCED MIXERS
6. 11.6 DOUBLE-BALANCED TRANSISTOR MIXERS
7. 11.7 SPURIOUS RESPONSE
8. 11.8 SINGLE-SIDEBAND NOISE FACTOR AND NOISE TEMPERATURE
9. 11.9 SPECIAL MIXER APPLICATIONS
10. 11.10 CONCLUSIONS
CHAPTER TWELVE Phase-Lock Loops
1. 12.1 INTRODUCTION
2. 12.2 PLL DESIGN BACKGROUND
3. 12.3 PLL APPLICATIONS
4. 12.4 PLL BASICS
5. 12.5 LOOP DESIGN PRINCIPLES
6. 12.6 LINEAR ANALYSIS OF THE PLL [5]*
7. 12.7 LOCKING A PHASE-LOCK LOOP
8. 12.8 LOOP TYPES
9. 12.9 NEGATIVE FEEDBACK IN A PLL
10. 12.10 PLL DESIGN EQUATIONS
11. 12.11 PHASE DETECTOR TYPES
12. 12.12 DESIGN EXAMPLES
13. 12.13 CONCLUSIONS
APPENDIX A Example of a Solenoid Design
APPENDIX B Analytical Spiral Inductor Model
APPENDIX C Double-Tuned Matching Circuit Example
APPENDIX D Two-Port Parameter Conversion
APPENDIX E Termination of a Transistor Port with a Load
APPENDIX F Transistor and Amplifier Formulas
1. BIPOLAR TRANSISTOR PARAMETERS (BJT)
2. JUNCTION FIELD-EFFECT TRANSISTOR PARAMETERS (JFET)
3. METAL–OXIDE SEMICONDUCTOR FIELD-EFFECT TRANSISTOR (MOSFET) PARAMETERS
4. SMALL-SIGNAL SINGLE-TRANSISTOR AMPLIFIER CONFIGURATIONS
APPENDIX G Transformed Frequency-Domain Measurements Using SPICE
1. G.1 INTRODUCTION
2. G.2 FREQUENCY-DOMAIN S PARAMETERS
3. G.3 TIME-DOMAIN REFLECTOMETRY ANALYSIS
4. G.4 TIME-DOMAIN IDENTIFICATION OF CIRCUIT ELEMENTS
5. G.5 MULTIPLE DISCONTINUITIES
6. G.6 SAMPLE SPICE LIST
7. G.7 IMPULSE RESPONSE SPICE NET LIST MODIFICATION
8. Acknowledgment
APPENDIX H Single-Tone Intermodulation Distortion Suppression for Double-Balanced Mixers
Index

Radio Frequency Circuit Design, 2nd Edition

Book Description

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