Muutke küpsiste eelistusi

Electronic Devices and Circuit Theory 11th edition [Kõva köide]

4.14/5 (605 hinnangut Goodreads-ist)
,
  • Formaat: Hardback, 944 pages, kõrgus x laius x paksus: 10x10x10 mm, kaal: 1890 g
  • Ilmumisaeg: 24-May-2012
  • Kirjastus: Pearson
  • ISBN-10: 0132622262
  • ISBN-13: 9780132622264
Teised raamatud teemal:
Electronic Devices and Circuit Theory 11th editionSuurem pilt
  • Formaat: Hardback, 944 pages, kõrgus x laius x paksus: 10x10x10 mm, kaal: 1890 g
  • Ilmumisaeg: 24-May-2012
  • Kirjastus: Pearson
  • ISBN-10: 0132622262
  • ISBN-13: 9780132622264
Teised raamatud teemal:
Püsilink: https://www.kriso.ee/db/9780132622264.html
Märksõnad:

Electronic Devices and Circuit Theory, Eleventh Edition, offers a complete, comprehensive survey, focusing on all the essentials you will need to succeed on the job. Setting the standard for nearly 30 years, this highly accurate text is supported by strong pedagogy and content that is ideal for new students of this rapidly changing field. The colorful layout with ample photographs and examples helps you better understand important topics. This text is an excellent reference work for anyone involved with electronic devices and other circuitry applications, such as electrical and technical engineers.

Preface v
Chapter 1 Semiconductor Diodes
1(54)
1.1 Introduction
1(1)
1.2 Semiconductor Materials: Ge, Si, and GaAs
2(1)
1.3 Covalent Bonding and Intrinsic Materials
3(2)
1.4 Energy Levels
5(2)
1.5 n-Type and p-Type Materials
7(3)
1.6 Semiconductor Diode
10(10)
1.7 Ideal Versus Practical
20(1)
1.8 Resistance Levels
21(6)
1.9 Diode Equivalent Circuits
27(3)
1.10 Transition and Diffusion Capacitance
30(1)
1.11 Reverse Recovery Time
31(1)
1.12 Diode Specification Sheets
32(3)
1.13 Semiconductor Diode Notation
35(1)
1.14 Diode Testing
36(2)
1.15 Zener Diodes
38(3)
1.16 Light-Emitting Diodes
41(7)
1.17 Summary
48(1)
1.18 Computer Analysis
49(6)
Chapter 2 Diode Applications
55(74)
2.1 Introduction
55(1)
2.2 Load-Line Analysis
56(5)
2.3 Series Diode Configurations
61(6)
2.4 Parallel and Series-Parallel Configurations
67(3)
2.5 AND/OR Gates
70(2)
2.6 Sinusoidal Inputs; Half-Wave Rectification
72(3)
2.7 Full-Wave Rectification
75(3)
2.8 Clippers
78(7)
2.9 Clampers
85(3)
2.10 Networks with a dc and ac Source
88(3)
2.11 Zener Diodes
91(7)
2.12 Voltage-Multiplier Circuits
98(3)
2.13 Practical Applications
101(10)
2.14 Summary
111(1)
2.15 Computer Analysis
112(17)
Chapter 3 Bipolar Junction Transistors
129(31)
3.1 Introduction
129(1)
3.2 Transistor Construction
130(1)
3.3 Transistor Operation
130(1)
3.4 Common-Base Configuration
131(5)
3.5 Common-Emitter Configuration
136(7)
3.6 Common-Collector Configuration
143(1)
3.7 Limits of Operation
144(1)
3.8 Transistor Specification Sheet
145(4)
3.9 Transistor Testing
149(2)
3.10 Transistor Casing and Terminal Identification
151(1)
3.11 Transistor Development
152(2)
3.12 Summary
154(1)
3.13 Computer Analysis
155(5)
Chapter 4 DC Biasing-BJTs
160(93)
4.1 Introduction
160(1)
4.2 Operating Point
161(2)
4.3 Fixed-Bias Configuration
163(6)
4.4 Emitter-Bias Configuration
169(6)
4.5 Voltage-Divider Bias Configuration
175(6)
4.6 Collector Feedback Configuration
181(5)
4.7 Emitter-Follower Configuration
186(1)
4.8 Common-Base Configuration
187(2)
4.9 Miscellaneous Bias Configurations
189(3)
4.10 Summary Table
192(2)
4.11 Design Operations
194(5)
4.12 Multiple BJT Networks
199(6)
4.13 Current Mirrors
205(3)
4.14 Current Source Circuits
208(2)
4.15 pnp Transistors
210(1)
4.16 Transistor Switching Networks
211(4)
4.17 Troubleshooting Techniques
215(2)
4.18 Bias Stabilization
217(9)
4.19 Practical Applications
226(7)
4.20 Summary
233(2)
4.21 Computer Analysis
235(18)
Chapter 5 BJT AC Analysis
253(125)
5.1 Introduction
253(1)
5.2 Amplification in the AC Domain
253(1)
5.3 BJT Transistor Modeling
254(3)
5.4 The re Transistor Model
257(5)
5.5 Common-Emitter Fixed-Bias Configuration
262(3)
5.6 Voltage-Divider Bias
265(2)
5.7 CE Emitter-Bias Configuration
267(6)
5.8 Emitter-Follower Configuration
273(4)
5.9 Common-Base Configuration
277(2)
5.10 Collector Feedback Configuration
279(5)
5.11 Collector DC Feedback Configuration
284(2)
5.12 Effect of RL and Rs
286(5)
5.13 Determining the Current Gain
291(1)
5.14 Summary Tables
292(1)
5.15 Two-Port Systems Approach
292(8)
5.16 Cascaded Systems
300(5)
5.17 Darlington Connection
305(9)
5.18 Feedback Pair
314(5)
5.19 The Hybrid Equivalent Model
319(5)
5.20 Approximate Hybrid Equivalent Circuit
324(6)
5.21 Complete Hybrid Equivalent Model
330(7)
5.22 Hybrid π Model
337(1)
5.23 Variations of Transistor Parameters
338(2)
5.24 Troubleshooting
340(2)
5.25 Practical Applications
342(7)
5.26 Summary
349(3)
5.27 Computer Analysis
352(26)
Chapter 6 Field-Effect Transistors
378(44)
6.1 Introduction
378(1)
6.2 Construction and Characteristics of JFETs
379(7)
6.3 Transfer Characteristics
386(4)
6.4 Specification Sheets (JFETs)
390(4)
6.5 Instrumentation
394(1)
6.6 Important Relationships
395(1)
6.7 Depletion-Type MOSFET
396(6)
6.8 Enhancement-Type MOSFET
402(7)
6.9 MOSFET Handling
409(1)
6.10 VMOS and UMOS Power and MOSFETs
410(1)
6.11 CMOS
411(1)
6.12 MESFETs
412(2)
6.13 Summary Table
414(1)
6.14 Summary
414(2)
6.15 Computer Analysis
416(6)
Chapter 7 FET Biasing
422(59)
7.1 Introduction
422(1)
7.2 Fixed-Bias Configuration
423(4)
7.3 Self-Bias Configuration
427(4)
7.4 Voltage-Divider Biasing
431(5)
7.5 Common-Gate Configuration
436(3)
7.6 Special Case Vgsq = OV
439(1)
7.7 Depletion-Type MOSFETs
439(4)
7.8 Enhancement-Type MOSFETs
443(6)
7.9 Summary Table
449(1)
7.10 Combination Networks
449(3)
7.11 Design
452(3)
7.12 Troubleshooting
455(1)
7.13 p-Channel FETs
455(3)
7.14 Universal JFET Bias Curve
458(3)
7.15 Practical Applications
461(9)
7.16 Summary
470(1)
7.17 Computer Analysis
471(10)
Chapter 8 FET Amplifiers
481(64)
8.1 Introduction
481(1)
8.2 JFET Small-Signal Model
482(7)
8.3 Fixed-Bias Configuration
489(3)
8.4 Self-Bias Configuration
492(5)
8.5 Voltage-Divider Configuration
497(1)
8.6 Common-Gate Configuration
498(3)
8.7 Source-Follower (Common-Drain) Configuration
501(4)
8.8 Depletion-Type MOSFETs
505(1)
8.9 Enhancement-Type MOSFETs
506(1)
8.10 E-MOSFET Drain-Feedback Configuration
507(3)
8.11 E-MOSFET Voltage-Divider Configuration
510(1)
8.12 Designing FET Amplifier Networks
511(2)
8.13 Summary Table
513(3)
8.14 Effect of RL and Rsig
516(2)
8.15 Cascade Configuration
518(3)
8.16 Troubleshooting
521(1)
8.17 Practical Applications
522(8)
8.18 Summary
530(1)
8.19 Computer Analysis
531(14)
Chapter 9 BJT and JFET Frequency Response
545(62)
9.1 Introduction
545(1)
9.2 Logarithms
545(5)
9.3 Decibels
550(4)
9.4 General Frequency Considerations
554(3)
9.5 Normalization Process
557(2)
9.6 Low-Frequency Analysis-Bode Plot
559(5)
9.7 Low-Frequency Response-BJT Amplifier with RL
564(4)
9.8 Impact of Rs on the BJT Low-Frequency Response
568(3)
9.9 Low-Frequency Response-FET Amplifier
571(3)
9.10 Miller Effect Capacitance
574(2)
9.11 High-Frequency Response-BJT Amplifier
576(8)
9.12 High-Frequency Response-FET Amplifier
584(2)
9.13 Multistage Frequency Effects
586(2)
9.14 Square-Wave Testing
588(3)
9.15 Summary
591(1)
9.16 Computer Analysis
592(15)
Chapter 10 Operational Amplifiers
607(46)
10.1 Introduction
607(3)
10.2 Differential Amplifier Circuit
610(7)
10.3 BiFET, BiMOS, and CMOS Differential Amplifier Circuits
617(3)
10.4 Op-Amp Basics
620(3)
10.5 Practical Op-Amp Circuits
623(5)
10.6 Op-Amp Specifications-DC Offset Parameters
628(3)
10.7 Op-Amp Specifications-Frequency Parameters
631(3)
10.8 Op-Amp Unit Specifications
634(5)
10.9 Differential and Common-Mode Operation
639(4)
10.10 Summary
643(1)
10.11 Computer Analysis
644(9)
Chapter 11 Op-Amp Applications
653(30)
11.1 Constant-Gain Multiplier
653(4)
11.2 Voltage Summing
657(3)
11.3 Voltage Buffer
660(1)
11.4 Controlled Sources
661(2)
11.5 Instrumentation Circuits
663(4)
11.6 Active Filters
667(3)
11.7 Summary
670(1)
11.8 Computer Analysis
671(12)
Chapter 12 Power Amplifiers
683(39)
12.1 Introduction-Definitions and Amplifier Types
683(2)
12.2 Series-Fed Class A Amplifier
685(3)
12.3 Transformer-Coupled Class A Amplifier
688(7)
12.4 Class B Amplifier Operation
695(4)
12.5 Class B Amplifier Circuits
699(6)
12.6 Amplifier Distortion
705(4)
12.7 Power Transistor Heat Sinking
709(3)
12.8 Class C and Class D Amplifiers
712(2)
12.9 Summary
714(1)
12.10 Computer Analysis
715(7)
Chapter 13 Linear-Digital ICs
722(29)
13.1 Introduction
722(1)
13.2 Comparator Unit Operation
722(7)
13.3 Digital-Analog Converters
729(3)
13.4 Timer IC Unit Operation
732(4)
13.5 Voltage-Controlled Oscillator
736(2)
13.6 Phase-Locked Loop
738(4)
13.7 Interfacing Circuitry
742(3)
13.8 Summary
745(1)
13.9 Computer Analysis
745(6)
Chapter 14 Feedback and Oscillator Circuits
751(32)
14.1 Feedback Concepts
751(1)
14.2 Feedback Connection Types
752(6)
14.3 Practical Feedback Circuits
758(5)
14.4 Feedback Amplifier-Phase and Frequency Considerations
763(3)
14.5 Oscillator Operation
766(1)
14.6 Phase-Shift Oscillator
767(3)
14.7 Wien Bridge Oscillator
770(1)
14.8 Tuned Oscillator Circuit
771(3)
14.9 Crystal Oscillator
774(3)
14.10 Unijunction Oscillator
777(1)
14.11 Summary
778(1)
14.12 Computer Analysis
779(4)
Chapter 15 Power Supplies (Voltage Regulators)
783(28)
15.1 Introduction
783(1)
15.2 General Filter Considerations
784(2)
15.3 Capacitor Filter
786(3)
15.4 RC Filter
789(2)
15.5 Discrete Transistor Voltage Regulation
791(7)
15.6 IC Voltage Regulators
798(5)
15.7 Practical Applications
803(2)
15.8 Summary
805(1)
15.9 Computer Analysis
806(5)
Chapter 16 Other Two-Terminal Devices
811(30)
16.1 Introduction
811(1)
16.2 Schottky Barrier (Hot-Carrier) Diodes
811(4)
16.3 Varactor (Varicap) Diodes
815(4)
16.4 Solar Cells
819(5)
16.5 Photodiodes
824(2)
16.6 Photoconductive Cells
826(2)
16.7 IR Emitters
828(1)
16.8 Liquid-Crystal Displays
829(2)
16.9 Thermistors
831(2)
16.10 Tunnel Diodes
833(4)
16.11 Summary
837(4)
Chapter 17 pnpn and Other Devices
841(38)
17.1 Introduction
841(1)
17.2 Silicon-Controlled Rectifier
841(1)
17.3 Basic Silicon-Controlled Rectifier Operation
842(1)
17.4 SCR Characteristics and Ratings
843(2)
17.5 SCR Applications
845(4)
17.6 Silicon-Controlled Switch
849(2)
17.7 Gate Turn-Off Switch
851(1)
17.8 Light-Activated SCR
852(2)
17.9 Shockley Diode
854(1)
17.10 Diac
854(2)
17.11 Triac
856(1)
17.12 Unijunction Transistor
857(8)
17.13 Phototransistors
865(2)
17.14 Opto-Isolators
867(2)
17.15 Programmable Unijunction Transistor
869(5)
17.16 Summary
874(5)
Appendix A Hybrid Parameters-Graphical Determinations and Conversion Equations (Exact and Approximate)
879(6)
A.1 Graphical Determination of the h-Parameters
879(4)
A.2 Exact Conversion Equations
883(1)
A.3 Approximate Conversion Equations
883(2)
Appendix B Ripple Factor and Voltage Calculations
885(6)
B.1 Ripple Factor of Rectifier
885(1)
B.2 Ripple Voltage of Capacitor Filter
886(1)
B.3 Relation of Vdc and Vm to Ripple r
887(1)
B.4 Relation of Vr(rms) and Vm to Ripple r
888(1)
B.5 Relation Connecting Conduction Angle, Percentage Ripple, and peak/dc for Rectifier-Capacitor Filter Circuits
889(2)
Appendix C Charts and Tables
891(2)
Appendix D Solutions to Selected Odd-Numbered Problems
893(8)
Index 901