Microelectronic Circuits

Part I - Devices and Basic Circuits
	Chapter 1 - Signals and Amplifiers
		Introduction
		1.1 Signals
		1.2 Frequency Spectrum of Signals
		1.3 Analog and Digital Signals
		1.4 Amplifiers
		1.5 Circuit Models for Amplifiers
		1.6 Frequency Response of Amplifiers
		Summary
		Problems
	Chapter 2 - Operational Amplifiers
		Introduction
		2.1 The Ideal Op Amp
		2.2 The Inverting Configuration
		2.3 The Noninverting Configuration
		2.4 Difference Amplifiers
		2.5 Integrators and Differentiators
		2.6 DC Imperfections
		2.7 Effect of Finite Open-Loop Gain and Bandwidth on Circuit Performance
		2.8 Large-Signal Operation of Op Amps
		Summary
		Problems
	Chapter 3 - Semiconductors
		Introduction
		3.1 Intrinsic Semiconductors
		3.2 Doped Semiconductors
		3.3 Current Flow in Semiconductors
		3.4 The pn Junction with Open-Circuit Terminals (Equilibrium)
		3.5 The pn Junction with an Applied Voltage
		3.6 Capacitive Effects in the pn Junction
		Summary
		Problems
	Chapter 4 - Diodes
		Introduction
		4.1 The Ideal Diode
		4.2 Terminal Characteristics of Junction Diodes
		4.3 Modeling the Diode Forward Characteristic
		4.4 Operation in the Reverse Breakdown — Zener Diodes
		4.5 Rectifier Circuits
		4.6 Limiting and Clamping Circuits
		4.7 Special Diode Types
		Summary
		Problems
	Chapter 5 - MOS Field-Effect Transistors (MOSFETs)
		Introduction
		5.1 Device Structure and Physical Operation
		5.2 Current–Voltage Characteristics
		5.3 MOSFET Circuits at DC
		5.4 Applying the MOSFET in Amplifier Design
		5.5 Small-Signal Operation and Models
		5.6 Basic MOSFET Amplifier Configurations
		5.7 Biasing in MOS Amplifier Circuits
		5.8 Discrete-Circuit MOS Amplifiers
		5.9 The Body Effect and Other Topics
		Summary
		Problems
	Chapter 6 - Bipolar Junction Transistors (BJTs)
		Introduction
		6.1 Device Structure and Physical Operation
		6.2 Current–Voltage Characteristics
		6.4 Applying the BJT in Amplifier Design
		6.5 Small-Signal Operation and Models
		6.6 Basic BJT Amplifier Configurations
		6.7 Biasing in BJT Amplifier Circuits
		6.8 Discrete-Circuit BJT Amplifiers
		6.9 Transistor Breakdown and Temperature Effects
		Summary
		Problems
Part II - Integrated-Circuit Amplifiers
	Chapter 7 - Building Blocks of Integrated-Circuit Amplifiers
		Introduction
		7.1 IC Design Philosophy
		7.2 The Basic Gain Cell
		7.3 The Cascode Amplifier
		7.4 IC Biasing—Current Sources, Current Mirrors, and Current-Steering Circuits
		7.5 Current-Mirror Circuits with Improved Performance
		7.6 Some Useful Transistor Pairings
		Summary
		Problems
	Chapter 8 - Differential and Multistage Amplifiers
		Introduction
		8.1 The MOS Differential Pair
		8.2 Small-Signal Operation of the MOS Differential Pair
		8.3 The BJT Differential Pair
		8.4 Other Nonideal Characteristicsof the Differential Amplifier
		8.5 The Differential Amplifier with Active Load
		8.6 Multistage Amplifiers
		Summary
		Problems
	Chapter 9 - Frequency Response
		Introduction
		9.1 Low-Frequency Response of the Common-Source and Common-Emitter Amplifiers
		9.2 Internal Capacitive Effects and the High-Frequency Model of the MOSFET and the BJT
		9.3 High-Frequency Response of the CS and CE Amplifiers
		9.4 Useful Tools for the Analysis of the High-Frequency Response of Amplifiers
		9.5 A Closer Look at the High-Frequency Response of the CS and CE Amplifiers
		9.6 High-Frequency Response of the Common-Gate and Cascode Amplifiers
		9.7 High-Frequency Response of the Source and Emitter Followers
		9.8 High-Frequency Response of Differential Amplifiers
		9.9 Other Wideband Amplifier Configurations
		9.10 Multistage Amplifier Examples
		Summary
		Problems
	Chapter 10 - Feedback
		Introduction
		10.1 The General Feedback Structure
		10.2 Some Properties of Negative Feedback
		10.3 The Four Basic Feedback Topologies
		10.4 The Feedback Voltage Amplifier (Series–Shunt)
		10.5 The Feedback Transconductance Amplifier (Series–Series)
		10.6 The Feedback Transresistance Amplifier (Shunt–Shunt)
		10.7 The Feedback Current Amplifier (Shunt–Series)
		10.8 Summary of the Feedback Analysis Method
		10.9 Determining the Loop Gain
		10.10 The Stability Problem
		10.11 Effect of Feedback on the Amplifier Poles
		Summary
		Problems
	Chapter 11 - Output Stages and Power Amplifiers
		Introduction
		11.1 Classification of Output Stages
		11.2 Class A Output Stage
		11.3 Class B Output Stage
		11.4 Class AB Output Stage
		11.5 Biasing the Class AB Circuit
		11.6 CMOS Class AB Output Stages
		11.7 Power BJTs
		11.8 Variations on the Class AB Configuration
		11.9 IC Power Amplifiers
		11.10 MOS Power Transistors
		Summary
		Problems
	Chapter 12 - Operational-Amplifier Circuits
		Introduction
		12.1 The Two-Stage CMOS Op Amp
		12.2 The Folded-Cascode CMOS Op Amp
		12.3 The 741 Op-Amp Circuit
		12.4 DC Analysis of the 741
		12.5 Small-Signal Analysis of the 741
		12.6 Gain, Frequency Response, and Slew Rate of the 741
		12.7 Modern Techniques for the Design of BJT Op Amps
		Summary
		Problems
Part III - Digital Integrated Circuits
	Chapter 13 - CMOS Digital Logic Circuit
		Introduction
		13.1 Digital Logic Inverters
		13.2 The CMOS Inverter
		13.3 Dynamic Operation of the CMOS Inverter
		13.4 CMOS Logic-Gate Circuits
		13.5 Implications of Technology Scaling: Issues inDeep-Submicron Design
		Summary
		Problems
	Chapter 14 - Advanced MOS and Bipolar Logic Circuits
		Introduction
		14.1 Pseudo-NMOS Logic Circuits
		14.2 Pass-Transistor Logic Circuits
		14.3 Dynamic MOS Logic Circuits
		14.4 Emitter-Coupled Logic (ECL)
		14.5 BiCMOS Digital Circuits
		Summary
		Problems
	Chapter 15 - Memory Circuits
		Introduction
		15.1 Latches and Flip-Flops
		15.2 Semiconductor Memories: Types and Architectures
		15.3 Random-Access Memory (RAM) Cells
		15.4 Sense Amplifiers and Address Decoders
		15.5 Read-only Memory (ROM)
		Summary
		Problems
Part IV - Filters and Oscillators
	Chapter 16 - Filters and Tuned Amplifiers
		Introduction
		16.1 Filter Transmission, Types, and Specification
		16.2 The Filter Transfer Function
		16.3 Butterworth and Chebyshev Filters
		16.4 First-Order and Second-Order Filter Functions
		16.5 The Second-Order LCR Resonator
		16.6 Second-Order Active Filters Based on Inductor Replacement
		16.7 Second-Order Active Filters Based on the Two-Integrator-Loop Topology
		16.8 Single-Amplifier Biquadratic Active Filters
		16.9 Sensitivity
		16.10 Switched-Capacitor Filters
		16.11 Tuned Amplifiers
		Summary
		Problems
	Chapter 17 - Signal Generators and Waveform-Shaping Circuits
		Introduction
		17.1 Basic Principles of Sinusoidal Oscillators
		17.2 Op Amp-RC Oscillator Circuits
		17.3 LC and Crystal Oscillators
		17.4 Bistable Multivibrators
		17.5 Generation of Square and Triangular Waveforms Using Astable Multivibrators
		17.6 Generation of a Standardized Pulse - The Monostable Multivibrator
		17.7 Integrated-Circuit Timers
		17.8 Nonlinear Waveform-Shaping Circuits
		17.9 Precision Rectifier Circuits
		Summary
		Problems
Appendixes on DVD
	Appendix A
	Appendix B
	Appendix C
	Appendix D
	Appendix E
	Appendix F
	Appendix G
Appendix
	Appendix H
	Appendix I
Bonus Topics
	THE JUNCTION FIELD-EFFECT  TRANSISTOR (JFET)
		Device Structure
		Physical Operation
		Current–Voltage Characteristics
		The p-Channel JFET
		The JFET Small-Signal Model
	GALLIUM ARSENIDE (GaAs) DEVICES—THE MESFET
		The Basic GaAs Devices
		Device Operation
		Device Characteristics and Models
		Current Sources
		A Cascode Current Source
		Increasing the Output Resistance by Bootstrapping
		A Simple Cascode Configuration – The Composite Transistor
		Differential Amplifiers
	GALLIUM-ARSENIDE DIGITAL CIRCUITS
		Direct-Coupled FET Logic (DCFL)
		Logic Gates Using Depletion MESFETs
		Schottky Diode FET Logic (SDFL)
		Buffered FET Logic (BFL)
	TRANSISTOR-TRANSISTOR LOGIC (TTL OR T2L)
		Evolution of TTL from DTL
		Reasons for the Slow Response of DTL
		Input Circuit of the TTL Gate
		Output Circuit of the TTL Gate
		The Complete Circuit of the TTL Gate
		Analysis When the Input Is High
		Analysis When the Input Is Low
		Function of the 130-0 Resistance
	CHARACTERISTICS OF STANDARD TTL
		Transfer Characteristic
		Manufacturers’ Specifications
		Propagation Delay
		Dynamic Power Dissipation
		The TTL NAND Gate
		Other TTL Logic Circuits
	TTL FAMILIES WITH IMPROVED PERFORMANCE
		Schottky TTL