Research Catalog

Analog integrated circuits for communication : principles, simulation and design

Title
Analog integrated circuits for communication : principles, simulation and design / Donald O. Pederson, Kartikeya Mayaram.
Author
Pederson, Donald O.
Publication
Berkeley, CA : Springer, [2008], ©2008.

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Additional Authors
Mayaram, Kartikeya.
Description
xvii, 533 pages : illustrations; 24 cm
Summary
"Analog Integrated Circuits for Communication: Principles, Simulation and Design, Second Edition covers the analysis and design of nonlinear analog integrated circuits that form the basis of present-day communication systems. Both bipolar and MOS transistor circuits are analyzed and several numerical examples are used to illustrate the analysis and design techniques developed in this book. Unique to this work is the tight coupling between the first-order circuit analysis and circuit simulation results. Extensive use has been made of the public domain circuit simulator Spice, to verify the results of first-order analyses, and for detailed simulations with complex device models."--BOOK JACKET.
Subject
  • Linear integrated circuits
  • Electronic circuit design
  • Telecommunication > Equipment and supplies
Note
  • First edition published by Kluwer, Boston, Dordrecht, 1991.
Contents
1. Review -- 1.1. Introduction -- 1.2. Amplitude and Frequency Modulations -- 1.3. The Super-Heterodyne Receiver -- 1.4. Transistor Models -- 1.5. Distortion Generation and Characterization -- 1.6. Noise -- 2. Large-Signal Performance of the Basic Gain Stages in Analog res -- 2.1. The Emitter-Coupled Pair -- 2.2. Large-Signal DC Transfer Characteristic of the ECP -- 2.3. Large-Signal Circuit Analysis of the ECP -- 2.4. Series Expansions to Obtain Distortion Components -- 2.5. The Source-Coupled Pair -- 2.6. A Series Expansion to Obtain Distortion Components for the SCP -- 3. Amplifier Power Series and Distortion -- 3.1. General Power Series Description -- 3.2. Common-Emitter Stage Example -- 3.3. The Ideal CE Stage with a Large Sinusoidal Input Voltage -- 3.4. Power Series and Fourier Series Characterizations -- 3.5. The Common-Source MOS Amplifier Stage -- 3.6. Intermodulation Distortion -- 3.7. Compression and Intercept Points -- 4. Distortion Generation with Source Resistance and Nonlinear Beta -- 4.1. Linearization of a Bipolar Stage Due to Source Resistance -- 4.2. Distortion Reduction with Source Resistance -- 4.3. The ECP with Source Resistance -- 4.4. Nonlinear Beta. and Distortion -- 4.5. Example of Distortion due to Beta(I[subscript c]) -- 5. Distortion in Feedback Amplifiers -- 5.1. Effects of Negative Feedback -- 5.2. Feedback for a General Amplifier -- 5.3. A CE Stage with Shunt Feedback -- 5.4. The CE Stage With Emitter Feedback -- 5.5. Alternative Loop-Gain Calculations -- 5.6. Emitter Feedback in the ECP -- 5.7. Internal Feedback in the ECP and the SCP -- 6. Basic IC Output Stages -- 6.1. Requirements for an Output Stage -- 6.2. The Emitter Follower -- 6.3. Distortion Calculation using Differential Error -- 6.4. Power-Conversion Efficiency -- 6.5. The Source Follower -- 6.6. Push-Pull Emitter Followers -- 6.7. The Push-Pull Source Follower -- 6.8. Push-Pull, Single-Polarity Output Stages -- 7. Transformers -- 7.1. Introduction -- 7.2. Elementary Coupled Coils -- 7.3. Circuit Model for a Transformer -- 7.4. Inductive Two-Port Parameters -- 7.5. A Transformer-Coupled, Class-A BJT Output Stage -- 7.6. Maximum Power Transfer -- 7.7. Class-A Push-Pull Operation -- 7.8. Class-AB Operation -- 8. Tuned Circuits in Bandpass Amplifiers -- 8.1. Introduction -- 8.2. The Single-Tuned Circuit -- 8.3. Lowpass Equivalents -- 8.4. Transformer-Coupled Single-Tuned Circuits -- 8.5. Single-Tuned, Bandpass Circuits with Loosely Coupled Transformers -- 8.6. Double-Tuned Stages -- 8.7. Parallel-to-Series/Series-to-Parallel Transformations -- 8.8. Tuned Circuits as Impedance Transformers -- 9. Simple Bandpass Amplifiers -- 9.1. Simple Active RC Bandpass Amplifiers -- 9.2. An ECP Bandpass Amplifier -- 9.3. Synchronous Tuning, Cascading, and Bandwidth Shrinkage -- 9.4. Effects of Internal Feedback -- 9.5. Multistage Bandpass Design Example -- 9.6. Cross Modulation -- 10. Basic Electronic Oscillators -- 10.1. Instabilities, Oscillations and Oscillators -- 10.2. The Ideal Electronic Oscillator -- 10.3. A Tunnel-Diode Oscillator -- 10.4. The van der Pol Approximation -- 10.5. Tunnel-Diode Oscillator Example -- 10.6. Wien-Type Oscillators -- 10.7. Transformer-Coupled ECP Oscillators -- 10.8. Transformerless ECP Oscillators -- 11. Electronic Oscillators with Bias-Shift Limiting -- 11.1. Bias Shift during Oscillator Buildup in an ECP Oscillator -- 11.2. The Basic Oscillator Equation -- 11.3. Single-Device, Transformer-Coupled Oscillators -- 11.4. Bias Shift and Harmonic Balance -- 11.5. Transformer-Coupled MOS Oscillators -- 11.6. Squegging -- 11.7. Phase-Shift Oscillators -- 11.8. The Colpitts Oscillator -- 11.9. Crystal-Controlled Oscillators -- 12. Relaxation and Voltage-Controlled Oscillators -- 12.1. Relaxation-Mode Oscillations -- 12.2. Oscillator Graphical Analysis -- 12.3. Regenerative Switching in a Relaxation Oscillator -- 12.4. Recovery Analysis in a Relaxation Feedback Oscillator -- 12.5. Other Astable Oscillators -- 12.6. A CMOS Relaxation Oscillator -- 12.7. Voltage- and Current-Controlled Oscillators -- 12.8. An Astable Schmitt Circuit -- 12.9. Equivalence of the Schmitt and Loop-Coupled Bistable Circuits -- 12.10. A BJT VCO -- 13. Analog Multipliers, Mixers, Modulators -- 13.1. The Emitter-Coupled Pair as a Simple Analog Multiplier -- 13.2. A Subtraction Improvement -- 13.3. Predistortion and Linearity Improvement in the ECP -- 13.4. The Gilbert Cell -- 13.5. MOS Analog Multipliers -- 13.6. Mixing, Modulation and Frequency Translation -- 13.7. The Fully Balanced (Quad) Mixer -- 13.8. Single-Device Mixers -- 13.9. Modulators -- 14. Demodulators and Detectors -- 14.1. AM Demodulation using Analog Multipliers -- 14.2. Synchronous AM Detection -- 14.3. Peak Detectors -- 14.4. Automatic Gain Control -- 14.5. FM Demodulation, Off-Peak Detection -- 14.6. Discriminators -- 14.7. FM Demodulators using Multipliers -- 15. Phase-Locked Loops -- 15.1. Basic Configurations and Applications -- 15.2. A Simple Circuit Model of a PLL -- 15.3. The Small-Signal Analysis of the PLL -- 15.4. Dynamics of the PLL in the Locked Condition -- 15.5. The Lock and Capture Ranges -- 15.6. PLLs with Overdriven PCs and Relaxation Oscillators -- 15.7. PLL Design Example -- 15.8. PLL Parameters for a Typical IC Realization -- 15.9. A PLL Example with a FM input.
ISBN
  • 9780387680293
  • 0387680292
OCLC
  • ocn124038172
  • SCSB-5387046
Owning Institutions
Columbia University Libraries