Introductory Electronic Devices and Circuits Electron Flow Version 7th Edition Paynter Test Bank

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Introductory Electronic Devices and Circuits Electron Flow Version 7th Edition Paynter Test Bank.

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Product Details:

  • ISBN-10 ‏ : ‎ 0131716395
  • ISBN-13 ‏ : ‎ 978-0131716391
  • Author:   Robert T. Paynter 

This book makes comprehension of material a top priority and encourages readers to be active participants in the learning process. The conventional-flow version of this book provides a readable and thorough approach to electronic devices and circuits, and support discussions with an abundance of learning aids to motivate and assist readers at every turn. The seventh edition of this well-established book features new internet link identifiers which bring the user to supplemental on-line resources. Covered topics include fundamental solid-state principles, common diode applications, amplifiers, oscillators and transistors. For professionals in the field of Electronics Technology.

 

Table of Content:

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 Circuit 
4.4 Emitter Bias 
4.5 Voltage-Divider Bias 
4.6 DC Bias with Voltage Feedback 
4.7 Miscellaneous Bias Configurations 
4.8 Design Operations 
4.9 Transistor Switching Networks 
4.10 Troubleshooting Techniques 
4.11 pnp Transistors 
4.12 Bias Stabilization 
4.13 Practical Applications 
4.14 Summary 
4.15 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 re Transistor Model 
5.5 The Hybrid Equivalent Model 
5.6 Hybrid Model P 
5.7 Variations of Transistor Parameters 
5.8 Common-Emitter Fixed-Bias Configuration 
5.9 Voltage-Divider Bias 
5.10 Common-Emitter Emitter-Bias Configuration 
5.11 Emitter-Follower Configuration 
5.12 Common-Base Configuration 
5.13 Collector Feedback Configuration 
5.14 Collector DC Feedback Configuration 
5.15 Determining the Current Gain 
5.16 Effect of RL and Rs 
5.17 Two-Port Systems Approach 
5.18 Summary Tables 
5.19 Cascaded Systems 
5.20 Darlington Connection 
5.21 Feedback Pair 
5.22 Current Mirror Circuits 
5.23 Current Source Circuits 
5.24 Approximate Hybrid Equivalent Circuit 
5.25 Complete Hybrid Equivalent Model 
5.26 Troubleshooting 
5.27 Practical Applications 
5.28 Summary 
5.29 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 Depletion-Type MOSFETs 
7.6 Enhancement-Type MOSFETs 
7.7 Summary Table 
7.8 Combination Networks 
7.9 Design 
7.10 Troubleshooting 
7.11 p-Channel FETs 
7.12 Universal JFET Bias Curve 
7.13 Practical Applications 
7.14 Summary 
7.15 Computer Analysis 
CHAPTER 8: FET Amplifiers 
8.1 Introduction 
8.2 FET Small-Signal Model 
8.3 JFET Fixed-Bias Configuration 
8.4 JFET Self-Bias Configuration 
8.5 JFET Voltage-Divider Configuration 
8.6 JFET Source-Follower (Common-Drain) Configuration 
8.7 JFET Common-Gate 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 RL and Rsig 
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 Low-Frequency Analysis--Bode Plot 
9.6 Low-Frequency Response--BJT Amplifier 
9.7 Low-Frequency Response--FET Amplifier 
9.8 Miller Effect Capacitance 
9.9 High-Frequency Response--BJT Amplifier 
9.10 High-Frequency Response--FET Amplifier 
9.11 Multistage Frequency Effects 
9.12 Square-Wave Testing 
9.13 Summary 
9.14 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 
	pnpn Devices 
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 
	Other Devices 
17.13 Unijunction Transistor 
17.14 Phototransistors 
17.15 Opto-Isolators 
17.16 Programmable Unijunction Transistor 
17.17 Summary 
Appendix A: Making the Chips That Run the World 
Appendix B: Hybrid Parameters--Graphical Determinations and Conversion Equations (Exact and 
Approximate) 
B.1 Graphical Determination of the h-Parameters 
B.2 Exact Conversion Equations 
B.3 Approximate Conversion Equations 
Appendix C: Ripple Factor and Voltage Calculations 
C.1 Ripple Factor of Rectifier 
C.2 Ripple Voltage of Capacitor Filter 
C.3 Relation of Vdc and Vm to Ripple r 
C.4 Relation of Vr (RMS) and Vm to Ripple r 
C.5 Relation Connecting Conduction Angle, Percentage Ripple, and IpeakIdc for Rectifier-Capacitor 
Filter Circuits
Appendix D: Charts and Tables 
Appendix E: Solutions to Selected Odd-Numbered Problems

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