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ویرایش: 1st ed. نویسندگان: Stephan J. G. Gift, Brent Maundy سری: ISBN (شابک) : 9783030469887, 9783030469894 ناشر: Springer International Publishing;Springer سال نشر: 2021 تعداد صفحات: 608 زبان: English فرمت فایل : PDF (درصورت درخواست کاربر به PDF، EPUB یا AZW3 تبدیل می شود) حجم فایل: 56 مگابایت
کلمات کلیدی مربوط به کتاب طراحی و کاربرد مدار الکترونیکی: مهندسی، مدارها و سیستم ها، مدارها و دستگاه های الکترونیکی
در صورت تبدیل فایل کتاب Electronic Circuit Design and Application به فرمت های PDF، EPUB، AZW3، MOBI و یا DJVU می توانید به پشتیبان اطلاع دهید تا فایل مورد نظر را تبدیل نمایند.
توجه داشته باشید کتاب طراحی و کاربرد مدار الکترونیکی نسخه زبان اصلی می باشد و کتاب ترجمه شده به فارسی نمی باشد. وبسایت اینترنشنال لایبرری ارائه دهنده کتاب های زبان اصلی می باشد و هیچ گونه کتاب ترجمه شده یا نوشته شده به فارسی را ارائه نمی دهد.
این کتاب درسی برای دروس اصلی در طراحی مدارهای الکترونیکی طراحی و کاربرد طیف وسیعی از مدارهای الکترونیکی آنالوگ را به شیوه ای جامع و واضح به دانش آموزان می آموزد. خوانندگان قادر به طراحی مدارها یا سیستم های کامل و کاربردی خواهند بود. نویسندگان ابتدا پایهای در تئوری و عملکرد دستگاههای الکترونیکی پایه، از جمله دیود، ترانزیستور پیوند دوقطبی، ترانزیستور اثر میدانی، تقویتکننده عملیاتی و تقویتکننده بازخورد جریان ارائه میکنند. آنها سپس دستورالعمل جامعی را در مورد طراحی مدارهای الکترونیکی واقعی و واقعی با سطوح مختلف پیچیدگی، از جمله تقویت کننده های قدرت، منابع تغذیه تنظیم شده، فیلترها، نوسان سازها و ژنراتورهای شکل موج ارائه می دهند. مثالهای زیادی به خواننده کمک میکند تا به سرعت با پارامترهای طراحی کلیدی و روششناسی طراحی برای هر دسته از مدارها آشنا شود. هر فصل از مدارهای اساسی شروع می شود و آنها را گام به گام در طیف گسترده ای از کاربردهای مدارها و سیستم های واقعی توسعه می دهد.
This textbook for core courses in Electronic Circuit Design teaches students the design and application of a broad range of analog electronic circuits in a comprehensive and clear manner. Readers will be enabled to design complete, functional circuits or systems. The authors first provide a foundation in the theory and operation of basic electronic devices, including the diode, bipolar junction transistor, field effect transistor, operational amplifier and current feedback amplifier. They then present comprehensive instruction on the design of working, realistic electronic circuits of varying levels of complexity, including power amplifiers, regulated power supplies, filters, oscillators and waveform generators. Many examples help the reader quickly become familiar with key design parameters and design methodology for each class of circuits. Each chapter starts from fundamental circuits and develops them step-by-step into a broad range of applications of real circuits and systems.
Preface Text Philosophy Text Philosophy Text Features Text Overview Closing Remarks Acknowledgments Contents Author Biographies Chapter 1: Semiconductor Diode 1.1 Theory of Semiconductors 1.1.1 Energy Levels 1.1.2 Intrinsic (Pure) Semiconductor 1.1.3 Extrinsic (Impure) Semiconductor 1.2 Current Flow in Semiconductor Diodes 1.2.1 Zero Bias 1.2.2 Reverse-Biased Diode 1.2.3 Forward-Biased Diode 1.3 General Characteristic of a Diode 1.3.1 Diode Specifications 1.4 Diode Types 1.4.1 Zener Diodes 1.4.2 Signal Diodes 1.4.3 Power Diodes 1.4.4 Varactor Diodes 1.4.5 Light-Emitting Diodes 1.4.6 Photodiodes 1.4.7 PIN Diodes 1.4.8 Schottky Diodes 1.5 Diode Circuits 1.5.1 DC Circuits 1.5.2 Clippers 1.5.3 Clampers 1.5.4 Half-Wave Rectifier 1.5.5 Full-Wave Rectifier 1.5.6 Bridge Rectifier 1.5.7 Zener Diode Regulators 1.6 Applications Problems Chapter 2: Bipolar Junction Transistor 2.1 Transistor Construction and Operation 2.2 Transistor Configurations 2.2.1 Common Emitter Configuration 2.2.2 Common Base Configuration 2.2.3 Common Collector Configuration 2.3 Common Emitter Amplifier 2.4 Alternative Biasing Methods 2.5 Common Base Amplifier 2.6 Common Collector Amplifier 2.7 Transistor Operating Limits and Specifications 2.8 Applications Problems Bibliography Chapter 3: Field-Effect Transistor 3.1 Operation of JFET 3.2 JFET Characteristics 3.3 JFET Parameters 3.4 Using the JFET as an Amplifier 3.4.1 Common Source Configuration 3.4.2 Common Drain Configuration 3.4.3 Common Gate Configuration 3.5 The MOSFET 3.5.1 Depletion-Type MOSFET 3.5.2 Enhancement-Type MOSFET 3.5.3 MOSFET Parameters 3.6 MOSFET Amplifiers 3.6.1 Depletion-Type MOSFET Common Source Amplifier 3.6.2 Depletion-Type MOSFET Common Drain Amplifier 3.6.3 Depletion-Type MOSFET Common Gate Amplifier 3.6.4 Enhancement-Type MOSFET Common Source Amplifier 3.6.5 Enhancement-Type MOSFET Common Drain Amplifier 3.6.6 Enhancement-Type MOSFET Common Gate Amplifier 3.7 Applications Problems Bibliography Chapter 4: BJT and FET Models 4.1 H-Parameters and the BJT 4.2 Analysis of a Common Emitter Amplifier Using H-Parameters 4.2.1 Common Emitter Amplifier with Partial Decoupling 4.2.2 Common Emitter Amplifier with Collector-Base Feedback Bias 4.3 Analysis of the Common Collector Amplifier Using H-Parameters 4.4 Analysis of the CB Amplifier Using H-Parameters 4.5 Y-Parameters and the FET 4.6 Analysis of the Common Source JFET Amplifier 4.7 Analysis of the Common Drain JFET Amplifier 4.8 Analysis of the Common Gate JFET Amplifier 4.9 Depletion MOSFET Common Source Amplifier 4.10 Depletion MOSFET Common Drain Amplifier 4.11 Depletion MOSFET Common Gate Amplifier 4.12 Enhancement MOSFET Common Source Amplifier 4.13 Enhancement MOSFET Common Drain Amplifier 4.14 Enhancement MOSFET Common Gate Amplifier 4.15 Applications Problems Bibliography Chapter 5: Multiple Transistor and Special Circuits 5.1 Cascaded Amplifiers 5.1.1 Direct Coupled High-Gain Configurations 5.2 Darlington Pair 5.3 Feedback Pair 5.4 Current Sources 5.5 Current Mirror 5.6 VBE Multiplier 5.7 Cascode Amplifier 5.8 Improved Emitter Follower 5.9 Differential Amplifier 5.10 BJT Switch 5.11 FET Switch 5.12 Voltage-Controlled Resistor 5.13 Applications Problems Bibliography Chapter 6: Frequency Response of Transistor Amplifiers 6.1 BJT Low-Frequency Response 6.1.1 Input Coupling Capacitor 6.1.2 Output Coupling Capacitor 6.1.3 Emitter Bypass Capacitor 6.2 FET Low-Frequency Response 6.3 Hybrid-Pi Equivalent Circuit 6.4 Miller Effect 6.5 Common Emitter Amplifier 6.6 Common Emitter Amplifier with Local Series Feedback 6.7 Common Emitter Amplifier with Local Shunt Feedback 6.8 High-Frequency Response of the Cascode Amplifier 6.9 High-Frequency Response of the Common Base Amplifier 6.10 High-Frequency Response of the Common Collector Amplifier 6.11 High-Frequency Response of a Common Source FET Amplifier 6.12 High-Frequency Response of a Common Gate FET Amplifier 6.13 High-Frequency Response of a Common Drain FET Amplifier 6.14 High-Frequency Response of Multistage Amplifiers 6.15 Applications Problems Bibliography Chapter 7: Feedback Amplifiers 7.1 Classification of Amplifiers 7.1.1 Voltage Amplifier 7.1.2 Current Amplifier 7.1.3 Transconductance Amplifier 7.1.4 Trans-resistance Amplifier 7.2 Feedback Amplifier Topologies 7.2.1 Voltage-Series Feedback 7.2.2 Voltage-Shunt Feedback 7.2.3 Current-Series Feedback 7.2.4 Current-Shunt Feedback 7.3 Transfer Gain with Feedback 7.4 Gain Stabilization Using Negative Feedback 7.5 Increase in Bandwidth Using Negative Feedback 7.6 Feedback and Harmonic Distortion 7.7 Input Resistance 7.7.1 Voltage-Series Feedback 7.7.2 Voltage-Shunt Feedback 7.7.3 Current-Series Feedback 7.7.4 Current-Shunt Feedback 7.8 Output Resistance 7.8.1 Voltage-Series Feedback 7.8.2 Voltage-Shunt Feedback 7.8.3 Current-Series Feedback 7.8.4 Current-Shunt Feedback 7.9 Analysis of Feedback Amplifiers 7.9.1 Voltage-Series Feedback 7.9.2 Current-Shunt Feedback 7.9.3 Current-Series Feedback 7.9.4 Voltage-Shunt Feedback 7.10 Voltage Amplifiers 7.11 Transistor Feedback Amplifier 7.12 Stability and Compensation 7.12.1 Compensating Feedback Amplifiers 7.13 Three-Transistor Feedback Amplifier 7.14 Applications Problems Bibliography Chapter 8: Operational Amplifiers 8.1 Introduction 8.2 The Inverting Amplifier 8.3 The Non-inverting Amplifier 8.4 Voltage Follower 8.5 Summing Amplifier 8.6 The Differential Amplifier 8.7 Integrator 8.8 Differentiator 8.9 Transimpedance Amplifier 8.10 Transconductance Amplifier 8.11 The Instrumentation Amplifier 8.12 A Realistic Operational Amplifier 8.12.1 Single Supply Operation 8.13 Frequency Effects 8.14 Non-ideal Effects 8.14.1 Offset Voltage and Currents 8.14.2 CMRR and PSRR 8.14.3 CMRR of the Instrumentation Amplifier 8.14.4 Slew Rate 8.15 The Current Feedback Amplifier 8.16 Applications Problems Bibliography Chapter 9: Power Amplifiers 9.1 Amplifier Classes 9.2 Fixed-Bias Class A Amplifier 9.2.1 Efficiency Calculations 9.3 Transformer-Coupled Class A Amplifier 9.4 Class B Push-Pull Amplifier 9.5 Low-Power Amplifier Design 9.6 Medium-Power Amplifier Design 9.7 High-Power Amplifier Design 9.8 High-Power MOSFET Amplifier 9.9 IC Power Amplifiers 9.10 Amplifier Accessories 9.10.1 Heatsink Design 9.11 Applications Problems Bibliography Chapter 10: Power Supplies 10.1 Basic System 10.2 Rectification 10.3 Filtering 10.4 Average DC Output Voltage 10.5 Bipolar Unregulated Power Supplies 10.6 Voltage Multipliers 10.7 Voltage Regulators 10.7.1 Ripple and Regulation 10.7.2 Zener Diode Regulator 10.7.3 Simple Series Transistor Regulator 10.7.4 Series Feedback Voltage Regulators 10.7.5 Protection Circuits 10.7.6 IC Voltage Regulators 10.7.7 Simple Approach to Regulated Power Supplies 10.8 Applications Problems Bibliography Chapter 11: Active Filters 11.1 Introduction to Filters 11.2 Basic First-Order LP Filter 11.2.1 Low-Pass Filter with Gain 11.3 Low-Pass Second-Order Filter 11.3.1 Sallen-Key or Voltage-Controlled Voltage Source (VCVS) Topology 11.3.2 Low-Pass Multiple Feedback Topology 11.4 Higher-Order Low-Pass Filters 11.4.1 Third-Order Low-Pass Unity-Gain Filter 11.5 High-Pass First-Order Filter-Butterworth Response 11.5.1 First-Order High-Pass Filter with Gain 11.6 High-Pass Second-Order Filter 11.6.1 Sallen-Key or Voltage-Controlled Voltage Source (VCVS) Topology 11.6.2 High-Pass Second-Order Multiple Feedback Filter 11.7 Higher-Order High-Pass Filters 11.7.1 Third-Order High-Pass Unity-Gain Filter 11.7.2 Band-Pass Filter 11.7.3 Sallen-Key Band-Pass Filter 11.7.4 Multiple Feedback Band-Pass Filter 11.7.5 Wien Band-Pass Filter 11.8 Band-Stop Filter 11.8.1 Twin-T Notch Filter 11.8.2 Wien Notch Filter 11.8.3 All-Pass Filters 11.8.4 First-Order All-Pass Filter Realization 11.9 State Variable Filter 11.9.1 Modified State Variable Filter 11.10 Applications Problems Bibliography Chapter 12: Oscillators 12.1 Conditions for Oscillation 12.2 RC Oscillators 12.2.1 Wien Bridge Oscillator 12.2.2 Phase Shift Oscillator-Lead Network 12.2.3 Phase Shift Oscillator-Lag Network 12.2.4 Buffered Phase Shift Oscillator 12.2.5 Multiphase Sinusoidal Oscillator 12.2.6 Quadrature Oscillator 12.2.7 Another Quadrature Oscillator 12.3 LC Oscillators 12.3.1 LC Resonant Oscillator 12.3.2 Colpitts and Hartley Oscillators 12.3.3 Clapp Oscillator 12.3.4 Simple LC Oscillator 12.4 Crystal Oscillators 12.4.1 Crystal Oscillator Using an Op-Amp 12.4.2 Miller Oscillator 12.4.3 Clapp Oscillator with Crystal Control 12.4.4 Pierce Crystal Oscillator 12.4.5 AD844 Crystal Oscillator 12.5 Frequency Stability 12.6 Amplitude Stabilization 12.7 Oscillator Creation 12.8 Applications Problems Bibliography Chapter 13: Waveform Generators and Non-linear Circuits 13.1 The Comparator 13.2 Square-Wave Generation 13.2.1 Sine Wave Generation from a Square-Wave Input 13.3 Triangular Wave Generation 13.3.1 Duty Cycle Modulation 13.3.2 Sawtooth Generation 13.3.3 Voltage-Controlled Oscillators 13.4 Monostable Multivibrators 13.4.1 The 555 Timer 13.5 Precision Rectifiers 13.5.1 Linear Half-Wave Rectifier 13.5.2 Signal Polarity Separator 13.5.3 Precision Rectifiers: The Absolute Value Circuit 13.5.4 High-Impedance Precision Full-Wave Rectifier 13.5.5 AC to DC Converter 13.6 Applications Problems Bibliography Chapter 14: Special Devices 14.1 Light-Dependent Resistor 14.2 Photodiode 14.3 Phototransistor 14.4 Opto-isolator 14.4.1 Photoresistor Opto-isolator 14.4.2 Photofet Opto-isolator 14.4.3 Photodiode Opto-isolator 14.4.4 Phototransistor Opto-isolator 14.4.5 Solid-State Relay 14.5 Silicon-Controlled Rectifier 14.5.1 Gate Turn-On Methods 14.5.2 Gate Turn-Off Switch 14.5.3 Light-Activated SCR 14.6 Triac 14.6.1 Triggering Methods 14.6.2 Phototriac Opto-isolator 14.7 Shockley Diode 14.8 Diac 14.9 Unijunction Transistor 14.10 Programmable Unijunction Transistor 14.11 Applications Problems Bibliography Index