Cover -- Contents -- Preface -- CHAPTER 1: Semiconductor Diodes -- 1.1 Introduction -- 1.2 Semiconductor Materials: Ge, Si, and GaAs -- 1.3 Covalent Bonding and Intrinsic Materials -- 1.4 Energy Levels -- 1.5 Extrinsic Materials: n-Type and p-Type -- 1.6 Semiconductor Diode -- 1.7 Ideal Versus Practical -- 1.8 Resistance Levels -- 1.9 Diode Equivalent Circuits -- 1.10 Transition and Diffusion Capacitance -- 1.11 Reverse Recovery Time -- 1.12 Diode Specification Sheets -- 1.13 Semiconductor Diode Notation -- 1.14 Diode Testing -- 1.15 Zener Diodes -- 1.16 Light-Emitting Diodes -- 1.17 Summary -- 1.18 Computer Analysis -- CHAPTER 2: Diode Applications -- 2.1 Introduction -- 2.2 Load-Line Analysis -- 2.3 Series Diode Configurations -- 2.4 Parallel and Series-Parallel Configurations -- 2.5 AND/OR Gates -- 2.6 Sinusoidal Inputs -- Half-Wave Rectification -- 2.7 Full-Wave Rectification -- 2.8 Clippers -- 2.9 Clampers -- 2.10 Zener Diodes -- 2.11 Voltage-Multiplier Circuits -- 2.12 Practical Applications -- 2.13 Summary -- 2.14 Computer Analysis -- CHAPTER 3: Bipolar Junction Transistors -- 3.1 Introduction -- 3.2 Transistor Construction -- 3.3 Transistor Operation -- 3.4 Common-Base Configuration -- 3.5 Transistor Amplifying Action -- 3.6 Common-Emitter Configuration -- 3.7 Common-Collector Configuration -- 3.8 Limits of Operation -- 3.9 Transistor Specification Sheet -- 3.10 Transistor Testing -- 3.11 Transistor Casing and Terminal Identification -- 3.12 Summary -- 3.13 Computer Analysis -- CHAPTER 4: DC Biasing-BJTs -- 4.1 Introduction -- 4.2 Operating Point -- 4.3 Fixed-Bias Configuration -- 4.4 Emitter Bias Configuration -- 4.5 Voltage-Divider Bias Configuration -- 4.6 Collector Feedback Configuration -- 4.7 Emitter-Follower Configuration -- 4.8 Common-Base Configuration -- 4.9 Miscellaneous Bias Configurations -- 4.10 Summary Table.

4.11 Design Operations -- 4.12 Current Mirror Circuits -- 4.13 Current Source Circuits -- 4.14 pnp Transistors -- 4.15 Transistor Switching Networks -- 4.16 Troubleshooting Techniques -- 4.17 Bias Stabilization -- 4.18 Practical Applications -- 4.19 Summary -- 4.20 Computer Analysis -- CHAPTER 5: BJT AC Analysis -- 5.1 Introduction -- 5.2 Application in the AC Domain -- 5.3 BJT Transistor Modeling -- 5.4 The r[sub(e)] Transistor Model -- 5.5 Common-Emitter Fixed-Bias Configuration -- 5.6 Voltage-Divider Bias -- 5.7 CE Emitter-Bias Configuration -- 5.8 Emitter-Follower Configuration -- 5.9 Common-Base Configuration -- 5.10 Collector Feedback Configuration -- 5.11 Collector DC Feedback Configuration -- 5.12 Determining the Current Gain -- 5.13 Effect of R[sub(L)] and R[sub(S)] -- 5.14 Summary Tables -- 5.15 Two-Port Systems Approach -- 5.16 Cascaded Systems -- 5.17 Darlington Connection -- 5.18 Feedback Pair -- 5.19 The Hybrid Equivalent Model -- 5.20 Approximate Hybrid Equivalent Circuit -- 5.21 Complete Hybrid Equivalent Model -- 5.22 Hybrid (Ss(B Model -- 5.23 Variations of Transistor Parameters -- 5.24 Troubleshooting -- 5.25 Practical Applications -- 5.26 Summary -- 5.27 Computer Analysis -- CHAPTER 6: Field-Effect Transistors -- 6.1 Introduction -- 6.2 Construction and Characteristics of JFETs -- 6.3 Transfer Characteristics -- 6.4 Specification Sheets (JFETs) -- 6.5 Instrumentation -- 6.6 Important Relationships -- 6.7 Depletion-Type MOSFET -- 6.8 Enhancement-Type MOSFET -- 6.9 MOSFET Handling -- 6.10 VMOS -- 6.11 CMOS -- 6.12 MESFETs -- 6.13 Summary Table -- 6.14 Summary -- 6.15 Computer Analysis -- CHAPTER 7: FET Biasing -- 7.1 Introduction -- 7.2 Fixed-Bias Configuration -- 7.3 Self-Bias Configuration -- 7.4 Voltage-Divider Biasing -- 7.5 Common-Gate Configuration -- 7.6 Special Case V[sub(GS[sub(Q)])] = 0 V -- 7.7 Depletion-Type MOSFETs.

7.8 Enhancement-Type MOSFETs -- 7.9 Summary Table -- 7.10 Combination Networks -- 7.11 Design -- 7.12 Troubleshooting -- 7.13 p-Channel FETs -- 7.14 Universal JFET Bias Curve -- 7.15 Practical Applications -- 7.16 Summary -- 7.17 Computer Analysis -- CHAPTER 8: FET Amplifiers -- 8.1 Introduction -- 8.2 JFET Small-Signal Model -- 8.3 Fixed-Bias Configuration -- 8.4 Self-Bias Configuration -- 8.5 Voltage-Divider Configuration -- 8.6 Common-Gate Configuration -- 8.7 Source-Follower (Common-Drain) Configuration -- 8.8 Depletion-Type MOSFETs -- 8.9 Enhancement-Type MOSFETs -- 8.10 E-MOSFET Drain-Feedback Configuration -- 8.11 E-MOSFET Voltage-Divider Configuration -- 8.12 Designing FET Amplifier Networks -- 8.13 Summary Table -- 8.14 Effect of R[sub(L)] and R[sub(sig)] -- 8.15 Cascade Configuration -- 8.16 Troubleshooting -- 8.17 Practical Applications -- 8.18 Summary -- 8.19 Computer Analysis -- CHAPTER 9: BJT and JFET Frequency Response -- 9.1 Introduction -- 9.2 Logarithms -- 9.3 Decibels -- 9.4 General Frequency Considerations -- 9.5 Normalization Process -- 9.6 Low-Frequency Analysis-Bode Plot -- 9.7 Low-Frequency Response-BJT Amplifier -- 9.8 Low-Frequency Response-FET Amplifier -- 9.9 Miller Effect Capacitance -- 9.10 High-Frequency Response-BJT Amplifier -- 9.11 High-Frequency Response-FET Amplifier -- 9.12 Multistage Frequency Effects -- 9.13 Square-Wave Testing -- 9.14 Summary -- 9.15 Computer Analysis -- CHAPTER 10: Operational Amplifiers -- 10.1 Introduction -- 10.2 Differential Amplifier Circuit -- 10.3 BiFET, BiMOS, and CMOS Differential Amplifier Circuits -- 10.4 Op-Amp Basics -- 10.5 Practical Op-Amp Circuits -- 10.6 Op-Amp Specifications-DC Offset Parameters -- 10.7 Op-Amp Specifications-Frequency Parameters -- 10.8 Op-Amp Unit Specifications -- 10.9 Differential and Common-Mode Operation -- 10.10 Summary -- 10.11 Computer Analysis.

CHAPTER 11: Op-Amp Applications -- 11.1 Constant-Gain Multiplier -- 11.2 Voltage Summing -- 11.3 Voltage Buffer -- 11.4 Controlled Sources -- 11.5 Instrumentation Circuits -- 11.6 Active Filters -- 11.7 Summary -- 11.8 Computer Analysis -- CHAPTER 12: Power Amplifiers -- 12.1 Introduction-Definitions and Amplifier Types -- 12.2 Series-Fed Class A Amplifier -- 12.3 Transformer-Coupled Class A Amplifier -- 12.4 Class B Amplifier Operation -- 12.5 Class B Amplifier Circuits -- 12.6 Amplifier Distortion -- 12.7 Power Transistor Heat Sinking -- 12.8 Class C and Class D Amplifiers -- 12.9 Summary -- 12.10 Computer Analysis -- CHAPTER 13: Linear-Digital ICs -- 13.1 Introduction -- 13.2 Comparator Unit Operation -- 13.3 Digital-Analog Converters -- 13.4 Timer IC Unit Operation -- 13.5 Voltage-Controlled Oscillator -- 13.6 Phase-Locked Loop -- 13.7 Interfacing Circuitry -- 13.8 Summary -- 13.9 Computer Analysis -- CHAPTER 14: Feedback and Oscillator Circuits -- 14.1 Feedback Concepts -- 14.2 Feedback Connection Types -- 14.3 Practical Feedback Circuits -- 14.4 Feedback Amplifier-Phase and Frequency Considerations -- 14.5 Oscillator Operation -- 14.6 Phase-Shift Oscillator -- 14.7 Wien Bridge Oscillator -- 14.8 Tuned Oscillator Circuit -- 14.9 Crystal Oscillator -- 14.10 Unijunction Oscillator -- 14.11 Summary -- 14.12 Computer Analysis -- CHAPTER 15: Power Supplies (Voltage Regulators) -- 15.1 Introduction -- 15.2 General Filter Considerations -- 15.3 Capacitor Filter -- 15.4 RC Filter -- 15.5 Discrete Transistor Voltage Regulation -- 15.6 IC Voltage Regulators -- 15.7 Practical Applications -- 15.8 Summary -- 15.9 Computer Analysis -- CHAPTER 16: Other Two-Terminal Devices -- 16.1 Introduction -- 16.2 Schottky Barrier (Hot-Carrier) Diodes -- 16.3 Varactor (Varicap) Diodes -- 16.4 Power Diodes -- 16.5 Tunnel Diodes -- 16.6 Photodiodes.

16.7 Photoconductive Cells -- 16.8 IR Emitters -- 16.9 Liquid-Crystal Displays -- 16.10 Solar Cells -- 16.11 Thermistors -- 16.12 Summary -- CHAPTER 17: pnpn and Other Devices -- 17.1 Introduction -- 17.2 Silicon-Controlled Rectifier -- 17.3 Basic Silicon-Controlled Rectifier Operation -- 17.4 SCR Characteristics and Ratings -- 17.5 SCR Construction and Terminal Identification -- 17.6 SCR Applications -- 17.7 Silicon-Controlled Switch -- 17.8 Gate Turn-Off Switch -- 17.9 Light-Activated SCR -- 17.10 Shockley Diode -- 17.11 Diac -- 17.12 Triac -- 17.13 Unijunction Transistor -- 17.14 Phototransistors -- 17.15 Opto-Isolators -- 17.16 Programmable Unijunction Transistor -- 17.17 Summary -- Appendix A: Hybrid Parameters-Graphical Determinations and Conversion Equations (Exact and Approximate) -- A.1 Graphical Determination of the h-Parameters -- A.2 Exact Conversion Equations -- A.3 Approximate Conversion Equations -- Appendix B: Ripple Factor and Voltage Calculations -- B.1 Ripple Factor of Rectifier -- B.2 Ripple Voltage of Capacitor Filter -- B.3 Relation of V[sub(dc)] and V[sub(m)] to Ripple r -- B.4 Relation of V[sub(r)](RMS) and V[sub(m)] to Ripple r -- B.5 Relation Connecting Conduction Angle, Percentage Ripple, and I[sub(peak)]/I[sub(dc)] for Rectifier-Capacitor Filter Circuits -- Appendix C: Charts and Tables -- Appendix D: Solutions to Selected Odd-Numbered Problems -- Index -- A -- B -- C -- D -- E -- F -- G -- H -- I -- J -- K -- L -- M -- N -- O -- P -- Q -- R -- S -- T -- U -- V -- W -- Z.

Electronic reproduction. Ann Arbor, Michigan : ProQuest Ebook Central, 2018. Available via World Wide Web. Access may be limited to ProQuest Ebook Central affiliated libraries.