电子电路分析与设计（影印版） (2008 年度畅销榜NO.5206 )

本书是美国知名大学广泛采用的教材。内容包括半导体器件及其基本应用、模拟电子技术和数字电子技术等三个部分。全书结构合理，层次清晰、文字流畅。书中具有丰富的例题和习题，而且不同层次的习题要求明确，很适于自学。本书还配有光盘（Virtual Lab CD-ROM）以辅助教学。\r\n\r\n

PART 1 SEMICONDUCTOR DEVICES AND BASIC APPLICATIONS\r\n\r\nChapter 1\r\n\r\nSemiconductor Materials and Diodes\r\n\r\n1.0 Preview\r\n1.1 Semiconductor Materials and Properties\r\n1.1.1 Intrinsic Semiconductors\r\n1.1.2 Extrinsic Semiconductors\r\n1.1.3 Drift and Diffusion Currents\r\n1.1.4 Excess Carriers\r\n1.2 The pn Junction\r\n1.2.1 The Equilibrium pn Junction\r\n1.2.2 Reverse-Biased pn Junction\r\n1.2.3 Forward-Biased pn Junction\r\n1.2.4 Ideal Current-Voltage Relationship\r\n1.2.5 pn Junction Diode\r\n1.3 Diode Circuits:DC Analysis and Models\r\n1.3.1 Iteration and Graphical Analysis Techniques\r\n1.3.2 Piecewise Linear Model\r\n1.3.3 Computer Simulation and Analysis\r\n1.3.4 Summary of Diode Models\r\n1.4 Diode Circuits:AC Equivalent Circuit\r\n1.4.1 Sinusoidal Analysis\r\n1.4.2 Small-Signal Equivalent Circuit\r\n1.5 Other Diode Types\r\n1.5.1 Solar Cell\r\n1.5.2 Photodiode\r\n1.5.3 Light-Emitting Diode\r\n1.5.4 Schottky Barrier Diode\r\n1.5.5 Zener Diode\r\n1.6 Summary\r\nCheckpoint\r\nReview Questions\r\nProblems\r\nComputer Simulation Problems\r\nDesign Problems\r\n\r\nChapter 2\r\n\r\nDiode Circuits\r\n\r\n2.0 Preview\r\n2.1 Rectifier Circuits\r\n2.1.1 Half-Wave Rectification\r\nProblem-Solving Technique:Diode Circuits\r\n2.1.2 Full-Wave Rectification\r\n2.1.3 Filters,Ripple Voltage,and Diode Current\r\n2.1.4 Voltage Doubler Circuit\r\n2.2 Zener Diode Circuits\r\n2.2.1 Ideal Voltage Reference Circuit\r\n2.2.2 Zener Resistance and Rercent Regulation\r\n2.3 Clipper and Clamper Circuits\r\n2.3.1 Clippers\r\n2.3.2 Clampers\r\n2.4 Multiple-Diode Circuits\r\n2.4.1 Example Diode Circuits\r\nProblem-Solving Technique:Multiple Diode Circuits\r\n2.4.2 Diode Logic Circuits\r\n2.5 Photodiode and LED Circuits\r\n2.5.1 Photodiode Circuit\r\n2.5.2 LED Circuit\r\n2.6 Summary\r\nCheckpoint\r\nReview Questions\r\nProblems\r\nComputer Simulation Problems\r\nDesign Problems\r\n\r\nChapter 3\r\n\r\nThe Bipolar Junction Transistor\r\n\r\n3.0 Preview\r\n3.1 Basic Bipolar Junction Transistor\r\n3.1.1 Transistor Structures\r\n3.1.2 npn Transistor:Forward-Active Mode Operation\r\n3.1.3 pnp Transistor:Forward-Active Mode Operation\r\n3.1.4 Circuit Symbols and Conventions\r\n3.1.5 Current-Voltage Characteristics\r\n3.1.6 Nonideal Transistor Leakage Currents and Breakdown\r\nVoltage\r\n3.2 DC Analysis of Transistor Circuits\r\n3.2.1 Common-Emitter Circuit\r\n3.2.2 Load Line and Modes of Operation\r\nProblem-Solving Technique:Bipolar DC Analysis\r\n3.2.3 Common Bipolar Circuits:DC Analysis\r\n3.3 Basic Transistor Applications\r\n3.3.1 Switch\r\n3.3.2 Digital Logic\r\n3.3.3 Amplifier\r\n3.4 Bipolar Transistor Biasing\r\n3.4.1 Single Base Resistor Biasing\r\n3.4.2 Voltage Divider Biasing and Bias Stability\r\n3.4.3 Integrated Circuit Biasing\r\n3.5 Multistage Circuits\r\n3.6 Summary\r\nCheckpoint\r\nReview Questions\r\nProblems\r\nComputer Simulation Problems\r\nDesign Problems\r\n\r\nChapter 4\r\n\r\nBasic BJT Amplifiers\r\n\r\n4.0 Preview\r\n4.1 Analog Signals and Linear Amplifiers\r\n4.2 The Bipolar Linear Amplifier\r\n4.2.1 Graphical Analysis and AC Equivalent Circuit\r\n4.2.2 Small-Signal Hybrid-π Equivalent Circuit of the Bipolar Transistor\r\nProblem-Sovlving Technique:Bipolar AC Analysis\r\n4.2.3 Hybrid-π Equivalent Circuit,Including the Early Effect\r\n4.2.4 Expanded Hybrid-π Equivalent Circuit\r\n4.2.5 Other Small-Signal Parameters and Equivalent Circuits\r\n4.3 Basic Transistor Amplifier Configurations\r\n4.4 Common-Emitter Amplifiers\r\n4.4.1 Basic Common-Emitter Amplifier Circuit\r\n4.4.2 Circuit with Emitter Resistor\r\n4.4.3 Circuit with Emitter-Bypass Capacitor\r\n4.4.4 Advanced Common-Emitter Amplifier Concepts\r\n4.5 AC Load Line Analysis\r\n4.5.1 AC Load Line\r\n4.5.2 Maximum Symmetrical Swing\r\nProblem-Solving Technique:Maximum Symmetrical Swing\r\n4.6 Common-Collector(Emitter-Follower)Amplifier\r\n4.6.1 Small-Signal Voltage Gain\r\n4.6.2 Input and Output Impedance\r\n4.6.3 Small-Signal Current Gain\r\n4.7 Common-Base Amplifier\r\n4.7.1 Small-Signal Voltage and Current Gains\r\n4.7.2 Input and Output Impedance\r\n4.8 The Three Basic Amplifiers:Summary and Comparison\r\n4.9 Multistage Amplifiers\r\n4.9.1 Multistage Analysis:Cascade Configuration\r\n4.9.2 Cascode Configuration\r\n4.10 Power Considerations\r\n4.11 Summary\r\nCheckpoint\r\nReview Questions\r\nProblems\r\nComputer Simulation Problems\r\nDesign Problems\r\n\r\nChapter 5\r\n\r\nThe Field-Effect Transistor\r\n\r\n5.0 Preview\r\n5.1 MOS Field-Effect Transistor\r\n5.1.1 Two-Terminal MOS Structure\r\n5.1.2 n-Channel Enhancement-Mode MOSFET\r\n5.1.3 Ideal MOSFET Current-Voltage Characteristics\r\n5.1.4 Circuit Symbols and Conventions\r\n5.1.5 Additional MOSFET Structures and Circuit Symbols\r\n5.1.6 Summary of Transistor Operation\r\n5.1.7 Nonideal Current-Voltage Characteristics\r\n5.2 MOSFET DC Circuit Analysis\r\n5.2.1 Common-source Circuit\r\n5.2.2 Load Line and modes of Operation\r\nProblem-Solving Technique:MOSFET DC Analysis\r\n5.2.3 Common MOSFET Configurations:DC Analysis\r\n5.2.4 Constant-Current Source Biasing\r\n5.3 Basic MOSFET Applications:Switch,Digital Logic Gate,and Amplifier\r\n5.3.1 NMOS Inverter\r\n5.3.2 Digital Logic Gate\r\n5.3.3 MOSFET Small-Signal Amplifier\r\n5.4 Junction Field-Effect Transistor\r\n5.4.1 pn JFET and MESFET Operation\r\n5.4.2 Current-Voltage Characteristics\r\n5.4.3 Common JFET Configurations:DC Analysis\r\n5.5 Summary\r\nCheckpoint\r\nReview Questions\r\nProblems\r\nComputer Simulation Problems\r\nDesign Problems\r\n\r\nChapter 6\r\n\r\nBasic FET Amplifiers\r\n\r\n6.0 Preview\r\n6.1 The MOSFET Amplifier\r\n6.1.1 Graphical Analysis,Load Lines,and Small-Signal arameters\r\n6.1.2 Small-Signal Equivalent Circuit\r\nProblem-Solving Technique:MOSFET AC Analysis\r\n6.1.3 Modeling the Body Effect\r\n6.2 Basic Transistor Amplifier Configurations\r\n6.3 The Common-Source Amplifier\r\n6.3.1 A Basic Common Source Configuration\r\n6.3.2 Common Source Amplifier with Source Resistor\r\n6.3.3 Common Source Circuit with Source Bypass Capacitor\r\n6.4 The Source-Follower Amplifier\r\n6.4.1 Small-Signal Voltage Gain\r\n6.4.2 Input and Output Impedance\r\n6.5 The Common-Gate Configuration\r\n6.5.1 Small-Signal Voltage and Current Gains\r\n6.5.2 Input and Output Impedance\r\n6.6 The Three Basic Amplifier configurations:Summary and Comparison\r\n6.7 Single-Stage Integrated Circuit MOSFET Amplifiers\r\n6.7.1 NMOS Amplifier with Enhancement Load\r\n6.7.2 NMOS Amplifier with Depletion Load\r\n6.7.3 NMOS Amplifier with PMOS Load\r\n6.8 Multistage Amplifiers\r\n6.8.1 DC Analysis\r\n6.8.2 Small-Signal Analysis\r\n6.9 Basic JFET Amplifiers\r\n6.9.1 Small-Signal Equivalent Circuit\r\n6.9.2 Small-Signal Analysis\r\n6.10 Summary\r\nCheckpoint\r\nReview Questions\r\nProblems\r\nComputer Simulation Problems\r\nDesign Problems\r\n\r\nChapter 7 \r\n\r\nFrequency Response\r\n\r\n7.0 Preview\r\n7.1 Amplifier Frequency Response\r\n7.1.1 Equivalent Circuits\r\n7.1.2 Frequency Response Analysis\r\n7.2 System Transfer Functions\r\n7.2.1 s-Domain Analysis\r\n7.2.2 First-Order Functions\r\n7.2.3 Bode Plots\r\n7.2.4 Short-Circuit and Open-Circuit Time Constants\r\n7.3 Frequency Response:Transistor Amplifiers with Circuit capacitors\r\n7.3.1 Coupling Capacitor Effects\r\nProblem-Solving Technique:Bode Plot of Gain Magnitude\r\n7.3.2 Load Capacitor Effects\r\n7.3.3 Coupling and Load Capacitors\r\n7.3.4 Bypass capacitor Effects\r\n7.3.5 Combined Effects:Coupling and Bypass Capacitors\r\n7.4 Frequency Response:Bipolar Transistor\r\n7.4.1 Expanded Hybrid-π Equivalent Circuit\r\n7.4.2 Short-Circuit Current Gain\r\n7.4.3 Cutoff Frequency\r\n7.4.4 Miller Effect and Miller Capacitance\r\n7.5 Frequency Response:The FET\r\n7.5.1 High-Frequency Equivalent Circuit\r\n7.5.2 Unity-Gain Bandwidth\r\n7.5.3 Miller Effect and Miller Capacitance\r\n7.6 High-Frequency Response of Transistor Circuits\r\n7.6.1 Common-Emitter and Common-Source Circuits\r\n7.6.2 Common-Base,Common-Gate,and Cascode Circuits\r\n7.6.3 Emitter-and Source-Follower Circuits\r\n7.6.4 High-Frequency Amplifier Design\r\n7.7 Summary\r\nCheckpoint\r\nReview Questions\r\nProblems\r\nComputer Simulation Problems\r\nDesign Problems\r\n\r\nChapter 8\r\n\r\nOutput Stages and Power Amplifiers\r\n\r\n8.0 Preview\r\n8.1 Power Amplifiers\r\n8.2 Power Transistors\r\n8.2.1 Power BJTs\r\n8.2.2 Power MOSFETs\r\n8.2.3 Heat Sinks\r\n8.3 Classes of Amplifiers\r\n8.3.1 Class-A Operation\r\n8.3.2 Class-B Operation\r\n8.3.3 Class-AB Operation\r\n8.3.4 Class-C Operation\r\n8.4 Class-A Power Amplifiers\r\n8.4.1 Inductively coupled Amplifier\r\n8.4.2 Transformer-Coupled Common-Emitter Amplifier\r\n8.4.3 Transformer-coupled Emitter-Follower Amplifier\r\n8.5 Class-AB Push-Pull Complementary Output Stages\r\n8.5.1 Class-AB Output Stage with Diode Biasing\r\n8.5.2 Class-AB Biasing Using the VBE Multiplier\r\n8.5.3 Class-AB Output Stage with ImputBuffer Transistors\r\n8.5.4 Class-AB Output Stage Utilizing the darlington\r\n8.6 Summary\r\nCheckpoint\r\nReview Questions\r\nProblems\r\nComputer Simulation Problems\r\nDesign Problems\r\n\r\nPART 2 ANALOG ELECTRONICS\r\n\r\nChapter 9\r\n\r\nThe Ideal Operational Amplifier\r\n\r\n9.0 Preview\r\n9.1 The Operational Amplifier\r\n9.1.1 Ideal Parameters\r\n9.1.2 Development of the Ideal Parameters\r\n9.1.3 Analysis Method\r\n9.1.4 PSpice Modeling\r\n9.2 Inverting Amplifier\r\n9.2.1 Basic Amplifier\r\nProblem-Solving Technique:Ideal Op-Amp Circuits\r\n9.2.2 Amplifier with a T-Network\r\n9.2.3 Effect of Finite Gain\r\n9.3 Summing Amplifier\r\n9.4 Noninverting Amplifier\r\n9.4.1 Basic Amplifier\r\n9.4.2 Voltage Follower\r\n9.5 Op-Amp Applications\r\n9.5.1 Current-to-Voltage Converter\r\n9.5.2 Voltage-to-Curretn Converter\r\n9.5.3 Difference Amplifier\r\n9.5.4 Instrumentation Amplifier\r\n9.5.5 Integrator and Differentiator\r\n9.5.6 Nonlinear circuit Applications\r\n9.6 Op-Amp Circuit Design\r\n9.6.1 Summing Op-Amp Circuit Design\r\n9.6.2 Reference Voltage Source Design\r\n9.6.3 Difference Amplifier and Bridge Circuit Design\r\n9.7 Summary\r\nCheckpoint\r\nReview Questions\r\nProblems\r\nComputer Simulation Problems\r\nDesign Problems\r\n\r\nChapter 10\r\n\r\nIntegrated Circuit Biasing and Active Loads\r\n\r\n10.0 Preview\r\n10.1 Bipolar Transistor Current Sources\r\n10.1.1 Two-Transistor Current Source\r\n10.1.2 Improved Current-Source Circuits\r\nProblem-Solving Technique:BJT Current Source Circuits\r\n10.1.3 Widlar Current Source\r\n10.1.4 Multitransistor Current Mirrors\r\n10.2 FET Current Sources\r\n10.2.1 Basic Two-Transistor MOSFET current Source\r\nProblem-Solving Technique:MOSFET Current-Source Circuit\r\n10.2.2 Multi-MOSFET Current-Source Circuits\r\n10.2.3 Bias-Independent Current Source\r\n10.2.4 JFET Current Sources\r\n10.3 Circuits with Active Loads\r\n10.3.1 DC Analysis:BJT Active Load Circuit\r\n10.3.2 Voltage Gain:BJT Active Load Circuit\r\n10.3.3 DC Analysis:MOSFET Active Load Circuit\r\n10.3.4 Voltage Gain:MOSFET Active Load Circuit\r\n10.3.5 Discussion\r\n10.4 Small-Sinnal Analysis:Active Load Circuits\r\n10.4.1 Small-Sinnal Analysis:BJT Active Load Circuit\r\nProblem-Solving Technique:Active Loads\r\n10.4.2 Small-Sinnal Analysis:MOSFET Active Load Circuit\r\n10.4.3 Small-Sinnal Analysis:Advanced MOSFET Active Load\r\n10.5 Summary\r\nCheckpoint\r\nReview Questions\r\nProblems\r\nComputer Simulation Problems\r\nDesign Problems\r\n\r\nChapter 11\r\n\r\nDifferential and Multistage Amplifiers\r\n\r\n11.0 Preview\r\n11.1 The Differential Amplifier\r\n11.2 Basic BJT Differential Pair\r\n11.2.1 Terminology and Qualitative Description\r\n11.2.2 DC Transfer Characteristics\r\n11.2.3 Small-Signal Equivalent Circuit Analysis\r\n11.2.4 Differential-and Common-Mode Gains\r\nProblem-Solving Technique:Diff-Amps with Resistive Loads\r\n11.2.5 Common-Mode Rejection Ratio\r\n11.2.6 Differential-and Common-Mode Input Impedances\r\n11.3 Basic FET Differential Pair\r\n11.3.1 DC Transfer Characteristics\r\n11.3.2 Differential-and Common-Mode Input Impedances\r\n11.3.3 Small-Signal Equivalent Circuit Analysis\r\n11.3.4 JFET Differential Amplifier\r\n11.4 Differential Amplifier with Active Load\r\n11.4.1 BJT Diff-Amp with Active Load\r\n11.4.2 Small-Signal Analysis of BJT Active Load\r\n11.4.3 MOSFET Differential Amplifier with Active Load\r\n11.4.4 MOSFET Diff-Amp with Cascode Active Load\r\n11.5 BiCMOS Circuits\r\n11.5.1 Basic Amplifier Stages\r\n11.5.2 Current Sources\r\n11.5.3 BiCMOS Differential Amplifier\r\n11.6 Gain Stage and Simple Output Stage\r\n11.6.1 Darlington Pair and Simple Emitter-Follower Output\r\n11.6.2 Input Impedance,Voltage Gain,and Output Impedance\r\n11.7 Simplified BJT Operational Amplifier Circuit\r\nProblem-Solving Technique:Multistage Circuits\r\n11.8 Diff-Amp Frequency Response\r\n11.8.1 Due to Differential-Mode Imput Signal\r\n11.8.2 Due to Common-Mode Input Signal\r\n11.8.3 With Emitter-Degeneration Resistors\r\n11.8.4 With Active Load\r\n11.9 Summary\r\nCheckpoint\r\nReview Questions\r\nProblems\r\nComputer Simulation Problems\r\nDesign Problems\r\n\r\nChapter 12\r\n\r\nFeedback and Stability\r\n\r\n12.0 Preview\r\n12.1 Introduction to Feedback\r\n12.1.1 Advantages and Disadvantages of Negative Feedback\r\n12.1.2 Use of Computer Simulation\r\n12.2 Basic Feedback Concepts\r\n12.2.1 Ideal Closed-Loop Gain\r\n12.2.2 Gain Sensitivity\r\n12.2.3 Bandwidth Extension\r\n12.2.4 Noise Sensitivity\r\n12.2.5 Reduction of Nonlinear Distortion\r\n12.3 Ideal Feedback Topologies\r\n12.3.1 Series-Shunt configuration\r\n12.3.2 Shunt-Series Configuration\r\n12.3.3 Series-Series Configuration\r\n12.3.4 Shunt-Shunt Configuration\r\n12.3.5 Summary of Results\r\n12.4 voltage(Series-Shunt)Amplifiers\r\n12.4.1 Op-Amp Circuit Representation\r\n12.4.2 Discrete Circuit Representation\r\n12.5 Current(Shunt-Series)Amplifiers\r\n12.5.1 Op-Amp Circuit Representation\r\n12.5.2 Simple Discrete Circuit Representation\r\n12.5.3 Discrete Circuit Representation\r\n12.6 Transconductance(Sereis-Series)Amplifiers\r\n12.6.1 Op-Amp Circuit Representation\r\n12.6.2 Discrete Circuit Representation\r\n12.7 Transresistance(Shunt-Shunt)Amplifiers\r\n12.7.1 Op-Amp Circuit Representation\r\n12.7.2 Discrete Circuit Representation\r\n12.8 Loop Gain\r\n12.8.1 Basic Approach\r\n12.8.2 Computer Analysis\r\n12.9 Stability of the Feedback Circuit\r\n12.9.1 The Stability Problem\r\n12.9.2 Bode Plots:One-,Two-,and Three-Pole Amplifiers\r\n12.9.3 Nyquist Stability Criterion\r\n12.9.4 Phase and Gain Margins\r\n12.10 Frequency Compensation\r\n12.10.1 Basic Theory\r\nProblem-Solving Technique:Frequency Compensation\r\n12.10.2 Closed-Loop Frequency Response\r\n12.10.3 Miller Compensation\r\n12.11 Summary\r\nCheckpoint\r\nReview Questions\r\nProblems\r\nComputer Simulation Problems\r\nDesign Problems\r\n\r\nChapter 13 \r\n\r\nOperational Amplifier Circuits\r\n\r\n13.0 Preview\r\n13.1 General Op-Amp Circuit Design\r\n13.1.1 General Design Philosophy\r\n13.1.2 Circuit Element Matching\r\n13.2 A Bipolar Operational Amplifier Circuit\r\n13.2.1 Circuit Description\r\n13.2.2 DC Analysis\r\n13.2.3 Small-Signal Analysis\r\n13.2.4 Frequency Response\r\nProblem-Solving Technique:Operational Amplifier circuits\r\n13.3 CMOS Operational Amplifier Circuits\r\n13.3.1 MC14573CMOS Operational Amplifier circuit\r\n13.3.2 Folded Cascode CMOS Operational Amplifier Circuit\r\n13.3.3 CMOS Current-Mirror Operational Amplifier Circuit\r\n13.3.4 CMOS Cascode Current-Mirror Op-Amp Circuit\r\n13.4 BiCMOS Operational Amplifier Circuit\r\n13.4.1 BiCMOS Folded Cascode Op-Amp\r\n13.4.2 CA3140 BiCMOS Circuit Description\r\n13.4.3 CA3140 DC Analysis\r\n13.4.4 CA3140 Small-Signal Analysis\r\n13.5 JFET Operational Amplifier Circuits\r\n13.5.1 Hybrid FET Op-Amp,LH0022/42/52 Series\r\n13.5.2 Hybrid FET Op-Amp,LF155 Series\r\n13.6 Summary\r\nCheckpoint\r\nReview Questions\r\nProblems\r\nComputer Simulation Problems\r\nDesign Problems\r\n\r\nChapter 14\r\n\r\nNonideal Effects in Operational Amplifier Circuits\r\n\r\n14.0 Preview\r\n14.1 Practical Op-Amp parameters\r\n14.1.1 Practical Op-Amp Parameter Definitions\r\n14.1.2 Input and Output Voltage Limitations\r\n14.2 Finite Open-Loop Gain\r\n14.2.1 Inverting Amplifier Closed-Loop Gain\r\n14.2.2 Noninverting Amplifier Closed-Loop Gain\r\n14.2.3 Inverting Amplifier Closed-Loop Input Resistance\r\n14.2.4 Noninverting Amplifier Closed-Loop Input Resistance\r\n14.2.5 Nonzero Output Resistance\r\n14.3 Frequency Response\r\n14.3.1 Open-Loop and Closed-Loop Frequency Response\r\n14.3.2 Gain-Bandwidth Product\r\n14.3.3 Slew Rate\r\n14.4 Offset Voltage\r\n14.4.1 Input Stage Offset Voltage Effects\r\n14.4.2 Offset Voltage compensation\r\n14.5 Input Bias Current\r\n14.5.1 Bias Current Effects\r\n14.5.2 Bias CurrentCompensation\r\n14.6 Additional Nonideal Effects\r\n14.6.1 Temperature Effects\r\n14.6.2 Common-Mode Rejection Ration\r\n14.7 Summary\r\nCheckpoint\r\nReview Questions\r\nProblems\r\nComputer Simulation Problems\r\nDesign Problems\r\n\r\nChapter 15\r\n\r\nApplications and Design of Integrated Circuits\r\n\r\n15.0 Preview\r\n15.1 Active Filters\r\n15.1.1 Active Network Design\r\n15.1.2 General Two-Pole Active Filter\r\n15.1.3 Two-pole Low-Pass Butterworth Filter\r\n15.1.4 Two-pole High-Pass Butterworth Filter\r\n15.1.5 Higer-Order Butterworth Filter\r\n15.1.6 Switched-Capacitor Filter\r\n15.2 Oscillators\r\n15.2.1 Basic Principles of Oscillation\r\n15.2.2 Phase-Shift Oscillator\r\n15.2.3 Wien-Bridge Oscillator\r\n15.2.4 Additional Osillator Configurations\r\n15.3 Schmitt Trigger Circuits\r\n15.3.1 Comparator\r\n15.3.2 Basic Inverting Schmitt Trigger\r\n15.3.3 Additional Schmitt Trigger Configurations\r\n15.3.4 Schmitt Triggers with Limiters\r\n15.4 Nonsinusoidal Oscillators and Timing Circuits\r\n15.4.1 Schmitt Trigger Oscillator\r\n15.4.2 monostable multivibrator\r\n15.4.3 The 555 Circuit\r\n15.5 Integrated Circuit Power Amplifiers\r\n15.5.1 LM 380 Power Amplifier\r\n15.5.2 PA 12 Power Amplifier\r\n15.5.3 Bridge Power Amplifier\r\n15.6 Voltage Regulators\r\n15.6.1 Basic Regulator Description\r\n15.6.2 Output Resistance and Load Regulation\r\n15.6.3 Simple Series-Pass Regulator\r\n15.6.4 Positive Voltage Regulator\r\n15.7 Summary\r\nCheckpoint\r\nReview Questions\r\nProblems\r\nComputer Simulation Problems\r\nDesign Problems\r\n\r\nPART 3 DIGITAL ELECTRONICS\r\n\r\nChpter 16\r\n\r\nMOSFET Digital Circuits\r\n\r\n16.0 Preview\r\n16.1 NMOS Inverters\r\n16.1.1 n-Channel MOSFET Revisited\r\n16.1.2 NMOS Inverter Transfer characteristics\r\n16.1.3 Noise Margin\r\n16.1.4 Body Effect\r\n16.1.5 Transient Analysis of NMOS Inverters\r\n16.2 NMOS Logic Circuits\r\n16.2.1 NMOS NOR and NAND Gates\r\n16.2.2 NMOS Logic Circuits\r\n16.2.3 Fanout\r\n16.3 CMOS Inverter\r\n16.3.1 p-Channel MOSFET Revisited\r\n16.3.2 DC Analysis of the CMOS Inverter\r\n16.3.3 Power Dissipation\r\n16.3.4 Noise Margin\r\n16.4 CMOS Logic Circuits\r\n16.4.1 Basic CMOS NOR and NAND Gates\r\n16.4.2 Complex CMOS Logic Circuits\r\n16.4.3 Fanout and Propagation Delay Time\r\n16.5 Clocked CMOS Logic Circuits\r\n16.6 Transmission Gates\r\n16.6.1 NMOS Transmission Gate\r\n16.6.2 NMOS Pass Networks\r\n16.6.3 CMOS Transmission Gate\r\n16.6.4 CMOS Pass Networks\r\n16.7 Sequential Logic Circuits\r\n16.7.1 Dynamic Shift Registers\r\n16.7.2 R-S Flip-Flop\r\n16.7.3 D Flip-Flop\r\n16.7.4 CMOS Full-Adder Circuit\r\n16.8 Memories:Classifications and Architectures\r\n16.8.1 Classifications of Memories\r\n16.8.2 Memory Architecture\r\n16.8.3 Address Decoders\r\n16.9 RAM Memory Cells\r\n16.9.1 NMOS SRAM Cells\r\n16.9.2 CMOS SRAM Cells\r\n16.9.3 SRAM Read/Write Circuitry\r\n16.9.4 Dynamic RAM(DRAM)Cells\r\n16.10 Read-Only Memory\r\n16.10.1 ROM and PROM Cells\r\n16.10.2 EPROM and EEPROM Cells\r\n16.11 Summary\r\nCheckpoint\r\nReview Questions\r\nProblems\r\nComputer Simulation Problems\r\nDesign Problems\r\n\r\nChapter 17\r\n\r\nBipolar Digital Circuits\r\n\r\n17.0 Preview\r\n17.1 Emitter-coupled Logic(ECL)\r\n17.1.1 Differential Amplifier Circuit Revisited\r\n17.1.2 Basic ECL Logic Gate\r\n17.1.3 ECL Logic Circuit Characteristics\r\n17.1.4 Voltage Transfer Characteristics\r\n17.2 Modified ECL Circuit Configurations\r\n17.2.1 Low-Power ECL\r\n17.2.2 Alternative ECL\r\n17.2.3 Series Gating\r\n17.2.4 Propagation Delay Time\r\n17.3 Transistor-Transistor Logic\r\n17.3.1 Basic Diode-Transistor Logic Gate\r\n17.3.2 The Input Transistor of TTL\r\n17.3.3 Basic TTL NAND Circuit\r\n17.3.4 TTL Output Stages and Fanout\r\n17.3.5 Tristate Output\r\n17.4 Schottky Transistor-Transistor Logic\r\n17.4.1 Schottky Clamped Transistor\r\n17.4.2 Schottky TTL NAND Circuit\r\n17.4.3 Low-Power Schottky TTL Circuits\r\n17.4.4 Advanced Schottky TTL Circuits\r\n17.5 BiCMOS Digital Circuits\r\n17.5.1 BiCMOS Inverter\r\n17.5.2 BiCMOS Logic Circuit\r\n17.6 Summary\r\nCheckpoint\r\nReview Questions\r\nProblems\r\nComputer Simulation Problems\r\nDesign Problems\r\n\r\nAPPENDIXES\r\n\r\nAppendix A\r\nPhysical Constants and Conversion Factors\r\n\r\nAppendix B\r\nIntroduction to Pspice\r\n\r\nB.0 Preview\r\nB.1 Introduction\r\nB.2 Drawing the Circuit\r\nB.3 Type of Analysis\r\nB.4 Displaying Results of Simulation\r\nB.5 Example Analyses\r\n\r\nAppendix C\r\nSelected Manufacturers’Data Sheets\r\n\r\nAppendix D\r\nStandard Resistor and Capacitor Values\r\n\r\nD.1 Carbon Resistors\r\nD.2 Precision Resistors(One Percent Tolerance)\r\nD.3 Capacitors\r\n\r\nAppendix E\r\nReading List\r\n\r\nAppendix F\r\nAnswers to Selected Problems\r\n\r\nIndex\r\n

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