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A collection of essential basic knowledge for electronic engineers

A collection of essential basic knowledge for electronic engineers, including classic series of books & analog and digital electronics word-of-mouth treasures. A must-have for beginners to improve, and a sentimental reading for veteran engineers.

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A collection of essential basic knowledge for electronic engineers Document List

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Electronic Engineer Self-study Quick Improvement Edition: Points it Requires : 3 Type:Technical DocumentationUploader:tywDate:2017-10-23; Introduction:\"Electronic Engineer Self-study Quick Course Improvement Edition\" was edited by Cai Xingshan and published in 2014. The \"Electronic Engineer Self-study Quick Course\" series is divided into 3 books: \"Introduction\", \"Advanced\" and \"Design\". \"Electronic Engineer Self-study Quick Course Improvement Edition\" is the \"Advanced Edition\", which includes two parts: analog circuits and digital circuits. The contents of the analog circuit part include the basics of circuit analysis, amplification circuits, amplifiers, resonant circuits, filter circuits, oscillators, modulation circuits, demodulation circuits, frequency conversion circuits, feedback control circuits, power supply circuits and thyristor circuits. The contents of the digital circuit part include the basics of digital circuits, gate circuits, number systems, coding, logical algebra, combinational logic circuits, sequential logic circuits, pulse circuits, D/A converters, A/D converters and semiconductor memories. \"Electronic Engineer Self-study Quick Course Improvement Edition\" has the characteristics of a low basic starting point, content from shallow to deep, easy-to-understand language, and a structure arrangement that conforms to the laws of learning and cognition. \"Electronic Engineer Self-study Quick Course Improvement Edition\" is suitable as a self-study book for electronic engineers to improve, and is also suitable as an electronic circuit textbook for vocational schools and social training institutions.

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《电子工程师必备：九大系统电路识图宝典》胡斌等编著人民邮电出版社: Points it Requires : 1 Type:Technical DocumentationUploader:tiankai001Date:2013-11-21; Introduction:《电子工程师必备：九大系统电路识图宝典》作者：胡斌吉玲胡松编著出版年: 2012-8 简介：本书从较高知识点起步，系统的介绍了九大类数十种功能电路和上百种单元电路的工作原理。书中对每一类型的电路均详细讲解其典型应用，对于同一种电路功能，均给出了不同形式的应用电路。本书可作为按前电路分析的手册典藏之作，适用于立志成为电子工程师的各级别读者参考。书中主要介绍的电路类型有：负反馈电路，放大电路，电源系统电路，扫描系统电路，音响系统电路，振荡系统电路，控制系统电路，数字系统电路等等

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Essential Basic Knowledge Handbook for Electronic Engineers (10 Volumes): Points it Requires : 3 Type:Technical DocumentationUploader:mayloveDate:2012-12-27; Introduction:A Handbook of Essential Basic Knowledge for Electronic Engineers (Ten Volumes in Total) This handbook is divided into ten volumes, which explain resistors, capacitors, inductors, transformers, semiconductor devices, relays, identification of commonly used components, power transistors, electroacoustic devices, and basic electronic concepts.

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\"Electronic Engineers Must-Have--Component Application Collection\" HD Bookmark Edition: Points it Requires : 3 Type:Technical DocumentationUploader:tywDate:2016-07-11; Introduction:\"Electronic Engineers\' Essentials - Component Application Handbook\" HD Bookmark Edition Author: Hu Bing, Liu Chao, Hu Song Publishing Year: 2012-9 Introduction: This book is an electronic component application manual. The book introduces various components and commonly used typical circuits. The specific content includes circuit symbol information explanation, appearance and model identification method, pin distribution rules and identification method, main characteristics explanation and characteristic curves, typical application circuit explanation, general function different circuit analysis, etc.

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Illustrated digital circuit 187 pages 2.8M.pdf: Points it Requires : 1 Type:Technical DocumentationUploader:tywDate:2013-08-22; Introduction:Illustrated digital circuit 187 pages 2.8M.pdf

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Electronics Enthusiasts\' Book - Introduction to Digital Circuits: Points it Requires : 1 Type:CourseUploader:tiankai001Date:2012-12-14; Introduction:1. Basic theory of digital circuits 2. Digital integrated circuits 3. Arithmetic circuits 4. Pulse circuits 5. Memory circuits 6. Counter circuits

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Huawei High-Speed Digital Circuit Design-Huawei Black Magic Book.pdf: Points it Requires : 1 Type:Technical DocumentationUploader:tywDate:2019-05-07; Introduction:Huawei High-Speed Digital Circuit Design-Huawei Black Book

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Selection of Typical Design Examples of Switching Power Supplies: Points it Requires : 3 Type:Technical DocumentationUploader:杨柳青年Date:2015-06-30; Introduction:Author: Yang Heng September 1, 2007 This book is divided into eight chapters. Chapter 1 briefly introduces 4 typical design examples of PFC. Chapter 2 systematically introduces 11 TV and LCD TV power supply designs and actual circuits. Chapter 3 introduces 12 specific circuits of adapter power supplies. Chapter 4 introduces 6 application circuits of charger power supplies. Chapter 5 introduces 12 industrial and PC power supply designs and actual circuits. Chapter 6 introduces 4 low-power power supplies. Chapter 7 introduces the design method and actual circuit of DC-DC power supplies with an output power of less than 100W. Chapter 8 introduces the design steps and application circuit of DC-DC power supplies with an output power of more than 100W. Each circuit in this book has a detailed calculation method and analysis of the working principle of the circuit. Each safety is accompanied by an actual circuit diagram. At the end of each case, a [special reminder] is made for the key content of the circuit. This book is based on the analysis and application of the latest switching power supply control IC. The topic is novel, fully combining theoretical analysis with practical application. It is rich in content, easy to explain, and has a fluent and easy-to-understand text. It has a high reference value.

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《开关电源的原理与设计》张占松，蔡宣三著: Points it Requires : 1 Type:Technical DocumentationUploader:空气Date:2013-08-05; Introduction:\"Principle and Design of Switching Power Supply\" by Zhang Zhansong and Cai Xuansan, publication year: 2004-9 Chapter 1 Basic Principles of PWM Switching Converter Chapter 1 Introduction to Switching Converter 1.1 What is a switching converter and switching power supply 1.2 DC-DC conversion Basic means and classification of DC-DC converters 1.3 Components and characteristics used in the main circuit of DC-DC converters 1.3.1 Switch 1.3.2 Inductor 1.3.3 Capacitor 1.4 Development history, current situation and trend of DC-DC converters 1.4.1 Switching power supply technology Development process 1.4.2 Main technologies that promoted the development of switching power supplies in the 20th century 1.4.3 Development direction of switching power supply technology 1.4.4 Large capacitor technology Chapter 2 Basic PWM converter main circuit topology 2.1 Buck converter 2.1.1 Line composition 2.1 .2 Working principle 2.1.3 Waveforms at each point of the circuit 2.1.4 Main concepts and relational expressions 2.1.5 Analysis of steady-state characteristics 2.2 Boost converter 2.2.1 Circuit composition 2.2.2 Working principle 2.2.3 Waveforms at each point of the circuit 2.2.4 Main concepts and relational expressions 2.2.5 Analysis of steady-state characteristics 2.2.6 Analysis and reduction methods of ripple voltage 2.3 Buck-Boost converter 2.3.1 Circuit composition 2.3.2 Working principle 2.3.3 Circuit points Waveform 2.3.4 Main concepts and relational expressions 2.3.5 Advantages and disadvantages 2.4 C＇uk converter 2.4.1 Line composition 2.4.2 Working principle 2.4.3 Waveforms at each point of the circuit 2.4.4 Main concepts and relational expressions 2.5 Four basic Comparison of three-level converters 2.6 Four basic three-level converters 2.6.1 Buck three-level converter circuit and working principle 2.6.2 Relationship between output voltage and output current of Buck three-level converter 2.6.3 Filter design 2.6.4 Boost, Buck-Boost C〖DD(-5/5〗＇〖DD)〗uk three-level converter Chapter 3 DC-DC converter topology with transformer isolator 3.1 Transformer isolator Ideal structure 3.2 Magnetic reset technology of single-ended transformer isolator 3.3 Working principle of self-excited push-pull converter 3.4 DC-DC transformer isolator with bidirectional energy flow 3.5 Isolated three-level converter 3.5.1 Forward conversion Converter 3L circuit 3.5.2 Half-bridge and full-bridge converter 3L circuit Chapter 4 Power switching components and drive circuits in converters 4.1 Bipolar transistors 4.1.1 The switching process of transistors 4.1.2 The physical meaning of switching time and Methods to reduce 4.1.3 Anti-saturation technology 4.2 Base drive circuit of bipolar transistor 4.2.1 General base drive circuit 4.2.2 High voltage bipolar transistor base drive circuit 4.2.3 Proportional base drive circuit 4.3 Power Field effect transistor 4.3.1 Main parameters of power field effect tube 4.3.2 Static characteristics of power field effect tube 4.3.3 Internal diode of MOSFET 4.4 Driving issues of power field effect tube 4.4.1 General requirements 4.4.2 MOSFET driving circuit 4.5 Insulated gate bipolar transistor 4.5.1 IGBT structure and working principle 4.5.2 Static operating characteristics of IGBT 4.5.3 Dynamic characteristics of IGBT 4.5.4 IGBT gate drive and its method 4.6 Safe operating area and protection of switching elements 4.6.1 Causes of secondary breakdown of bipolar transistors and its impact on SOA 4.6.2 Safe operating area (SOA) 4.6.3 Protection link - RC buffer Chapter 5 Characteristics and calculation of magnetic components 5.1 Overview 5.1.1 The role of magnetic components in switching power supplies 5.1.2 Master the importance of magnetic components to design 5.1.3 Description of the basic characteristics of magnetic materials 5.1.4 Comparison table of magnetic core models 5.2 Magnetic materials and ferrite magnetic materials 5.2.1 Magnetic properties of magnetic cores 5.2.2 Magnetic core structure 5.3 High-frequency transformer design method 5.3.1 One of the transformer design methods - area product (AP) method 5.3.2 The second transformer design method - geometric parameter (KG) method 5.4 Inductor design method 5.4.1 One of the inductor design methods - Area Product (AP) method 5.4.2 The second inductor design method - Geometric parameter (KG) method 5.4.3 Inductor design without DC bias 5.5 Suppression of spikes Wave coils and differential mode and common mode choke coils 5.5.1 Electromagnetic coils that suppress sharp waves 5.5.2 Differential mode and common mode choke coils 5.5.3 Suppression of interference when using twisted pairs 5.5.4 Suppression of interference when using cables Suppression 5.6 Characteristics and applications of amorphous and ultra-microcrystalline (nanocrystalline) alloy soft magnetic materials 5.6.1 Characteristics of amorphous alloy soft magnetic materials 5.6.2 Characteristics of ultra-microcrystalline alloy soft magnetic materials 5.6.3 Amorphous, ultra-micro Application of Crystal Alloy Soft Magnetic Materials Chapter 6 Principles and Applications of Switching Power Supply Duty Cycle Control Chip and Integrated Switching Converter 6.1 Isolation Technology of Switching Power Supply System 6.2 Switching Power Supply PWM Control Chip and Intelligent Power Switch 6.2.1 1524/2524/ Introduction to 3524 chip 6.2.2 Working process of the chip 6.3 IC chip suitable for power field effect tube control 6.3.1 Difference between 1525A and 1524 6.3.2 Application of 1525A/1527A 6.4 Current controlled pulse width modulator 6.4.1 UC1846/ UC1847 working principle and block diagram 6.4.2 1842/2842/3842 8-pin pulse width modulator 6.5 Intelligent power switch and its application 6.5.1 Overview 6.5.2 Working principle 6.6 Integrated block used in power supply in portable devices 6.6.1 Introduction 6.6. 2 Application of MAX863 chip 6.6.3 Application and design method of MAX624 chip Chapter 7 Power rectifier 7.1 Power rectifier diode 7.1.1 Power rectifier diode model 7.1.2 Main parameters of power diode 7.1.3 Several fast switching diodes 7.2 Synchronization Rectification technology 7.2.1 Overview 7.2.2 Basic principles of synchronous rectification technology 7.2.3 Synchronous rectification driving method 7.2.4 Synchronous rectification circuit 7.2.5 SR-Buck converter 7.2.6 SR-forward converter 7.2.7 SR- Flyback converter Chapter 8 Active power factor corrector 8.1 Input current harmonic component of AC-DC circuit 8.1.1 Harm of harmonic current to the power grid 8.1.2 Power factor at the input end of AC-DC converter circuit 8.1.3 Limitation of harmonic current at the input end of AC-DC circuit 8.1.4 Main methods to improve the power factor at the input end of AC-DC circuit and reduce input current harmonics 8.2 Power factor and THD 8.2.1 Definition of power factor 8.2.2 AC- The relationship between DC circuit input power factor and harmonics 8.3 Working principle of Boost power factor corrector (PFC) 8.3.1 Basic principles of power factor correction 8.3.2 Main advantages and disadvantages of Boost active power factor corrector (APFC) 8.4 APFC Control methods 8.4.1 Three commonly used control methods 8.4.2 Current peak control method 8.4.3 Current hysteresis control method 8.4.4 Average current control method 8.4.5 Introduction to PFC integrated control circuit UC3854A/B 8.5 Flyback power Factor corrector 8.5.1 Principle of DCM flyback power factor correction circuit 8.5.2 Equivalent input resistance Re 8.5.3 Average output current and output power 8.5.4 DCM flyback converter equivalent circuit average model Chapter 9 Current sharing technology of switching power supply parallel system 9.1 Overview 9.2 Common current sharing methods of switching power supply parallel system 9.2.1 Output impedance method 9.2.2 Master-slave setting method 9.2.3 Automatic current balancing by average current value 9.2.4 Automatic current balancing by maximum current method 9.2.5 Automatic current balancing by thermal stress 9.2.6 Current balancing by external current balancing controller Chapter 10 Small signal analysis and closed-loop stability and correction of switching power supplies 10.1 Overview 10.2 State space averaging method when inductor current is continuous 10.3 Standardized model of average equivalent circuit when current is continuous 10.4 Standardized model when current is discontinuous 10.5 Model of complex converter 10.6 Analysis of stability problem of switching power supply with input filter by small signal method 10.7 Control principle and stability problem of switching power supply 10.7.1 Closed-loop and open-loop control 10.7.2 Block diagram of switching power supply structure 10.8 Drawing of stability discriminant Bode plot 10.8.1 Amplitude-frequency characteristics and phase-frequency characteristics of common links 10.8.2 Method for quickly drawing open-loop logarithmic characteristic curve 10.8.3 Analysis of dynamic performance of system by open-loop characteristics 10.9 10.9.1 Direct injection method for open-loop system 10.9.2 Direct injection method for closed-loop circuit 10.10 Determine Bode plot and determine the parameters of error amplifier 10.10.1 TL431 related measurement technology 10.10.2 Design method to improve stability 10.10.3 Analysis of the trend of parameter change Part 2 Design and production of PWM switching converter [KH1D] Chapter 11 Design of flyback converter 11.1 Overview 11.1.1 Electromagnetic energy storage and conversion 11.1.2 Further explanation of working mode 11.1.3 Energy storage capacity of transformer 11.1.4 Synchronous rectification of flyback converter 11.2 Example of flyback converter design method 11.2.1 Main power circuit 11.2.2 Transformer design 11.2.3 Design of 112W flyback transformer 11.2.4 Several problems in design 11.2.5 Another method of calculating transformer 11.3 Snubber Design for Flyback Converter 11.3.1 Switching Stress of Flyback Converter 11.3.2 Tracking Collector Voltage Clamping Link 11.3.3 Working Waveform of Snubber Link 11.3.4 Determination of Snubber Parameters 11.3.5 Low Loss Snubber 11.4 Dual Transistor Flyback Converter 11.4.1 Overview 11.4.2 Working Principle 11.4.3 Working Characteristics 11.4.4 Snubber 11.4.5 Working Frequency 11.4.6 Driving Circuit 11.4.7 Pay Attention to Leakage Inductance and Number of Turns in Transformer Design Chapter 12 Design of Single-Ended Forward Converter 12.1 Overview 12.2 Working Principle 12.2.1 Minimum and Maximum Inductance 12.2.2 Multiple Outputs 12.2.3 Working Principle of Energy Regeneration Coil P2 12.2.4 Synchronous Rectification of Single-Ended Forward Converter 12.2.5 Advantages and Disadvantages of Forward Converter 12.3 Transformer Design Methods 12.3.1 Method 1 12.3.2 Method 2 Chapter 13 Design of Dual-Transistor Forward Converter 13.1 Overview 13.1.1 Circuit Composition 13.1.2 Working Principle 13.1.3 Function of Capacitor C 13.2 Dual-Transistor Forward Converter Transformer Design 13.3 Closed-Loop Control and Parameter Calculation of Forward Converter 13.3.1 UPC 1099 Limit Use Value and Main Electrical Performance 13.3.2 Application of UPC 1099 Chapter 14 Design of Half-Bridge Converter 14.1 Working Principle of Half-Bridge Converter 14.2 Bias Magnetic Phenomenon and Its Prevention Method 14.2.1 Possibility of Bias Magnetic Phenomenon 14.2.2 Improving Bias Magnetic Performance with Series Coupling Capacitor 14.2.3 Selection of Series Coupling Capacitor 14.2.4 Possibility of Step-by-Step Saturation and Its Prevention 14.2.5 Possibility of Shoot-Through and Its Prevention 14.3 Soft Start and Double Flux Effect 14.3.1 Chapter 15 Design of Bridge Converter 15.1 Overview 15.2 Working Principle 15.2.1 Overview 15.2.2 Working Process 15.2.3 Composition and Function of Snubber 15.2.4 Double Flux Effect during Transient 15.3 Transformer Design Method 15.3.1 Design Steps and Examples 15.3.2 Several Questions Chapter 16 Design of Dual-Drive Transformer Push-Pull Converter 16.1 Overview 16.1.1 Circuit Structure 16.1.2 Working Principle 16.1.3 Waveforms at Each Point 16.2 Buffering Link of Switching Power Tube 16.3 Design of Transformer in Push-Pull Converter Chapter 17 Design of High-Frequency Transformer with H7C1 Material and PQ Core 17.1 Introduction to Losses and Design Principles 17.1.1 Design Principles 17.1.2 Conditions for Meeting Design Principles 17.2 Tabular Curve Design Method 17.2.1 Formation and Explanation of Table 17.1 17.2.2 Expanding the Scope of Use of Table 17.1 Chapter 18 Design of Electronic Ballast 18.1 Overview 18.1.1 Fluorescent Lamp 18.1.2 Structure and V/I Characteristics of Fluorescent Lamp 18.1.3 Basic Structure of High-Frequency Electronic Ballast 18.2 Half-Bridge Series Resonant Electronic Ballast 18.3 Electronic Ballast with Active and Passive Power Factor Circuits 18.3.1 Active Power Factor Correction Electronic Ballast 18.3.2 Passive Power Factor Correction Electronic Ballast Chapter 19 Common Problems in Switching Power Supply Design and Production 19.1 Interference and Insulation 19.1.1 Interference Problems and Standards 19.1.2 Isolation and Insulation 19.2 Efficiency and Power Factor 19.2.1 High Efficiency and High Power Density 19.2.2 High Power Factor 19.3 Intelligence and High Reliability 19.4 High-frequency current effects and flat transformer design 19.4.1 Generation of skin effect and proximity effect 19.4.2 Design of flat transformer Part 3 Soft-switching-PWM converter Chapter 20 Soft-switching power conversion technology 20.1 Hard-switching technology and switching losses 20.2 High frequency and soft-switching technology 20.3 Zero current switching and zero voltage switching 20.4 Resonant converter 20.5 Quasi-resonant converter 20.6 Overview of multi-resonant converter Chapter 21 ZCS-PWM and ZVS-PWM conversion technology 21.1 ZCS-PWM converter 21.1.1 Working principle 21.1.2 Operation mode analysis 21.1.3 Analysis 21.1.4 Advantages and disadvantages of ZCS-PWM converter 21.2 ZVS-PWM converter 21.2.1 Working principle 21.2.2 Operation mode analysis 21.2.3 Analysis 21.2.4 Advantages and Disadvantages of ZVS-PWM Converter Chapter 22 Zero-Transition-PWM Soft Switching Conversion Technology 22.1 Zero-Transition-PWM Converter 22.2 ZCT-PWM Converter 22.2.1 Working Principle 22.2.2 Operation Mode Analysis 22.2.3 Advantages and Disadvantages of ZCT-PWM Converter 22.2.4 Numerical Analysis 22.3 Three-Terminal ZCT-PWM Switching Circuit 22.4 ZVT-PWM Converter 22.4.1 Working Principle 22.4.2 Operation Mode Analysis 22.4.3 Advantages and Disadvantages of ZVT-PWM Converter 22.4.4 Application Example 22.4.5 Three-Terminal Zero Voltage Switching Circuit 22.4.6 Two-Tube Forward ZVT-PWM Converter Chapter 23 Phase-Shifted Full-Bridge ZVS-PWM Converter 23.1 DC-DC FB ZVS-PWM DC-DC Converter Working Principle 23.2 PSC FB ZVS-PWM Converter Operation Mode Analysis 23.3 PSC FB Analysis of several issues of ZVS-PWM converter 23.3.1 Duty cycle analysis 23.3.2 Analysis of ZVS conditions of the two-leg switch tubes of PSC FB ZVS-PWM converter 23.4 PSC FB ZCZVS-PWM Converter Chapter 24 Active Clamp Soft Switching PWM Conversion Technology 24.1 Overview 24.2 Active Clamp Circuit 24.3 Active Clamp ZVS-PWM Forward Converter Steady-State Operation Analysis 24.4 Active Clamp Parallel Interleaved Flyback Converter 24.5 Active Clamp Flyback-Forward Converter Part 4 Computer-Aided Analysis and Design of Switching Power Supplies Chapter 25 Computer Simulation of Switching Power Supplies 25.1 Computer Simulation Technology of Power Electronic Circuits 25.1.1 Computer Simulation Technology 25.1.2 Circuit Simulation Analysis (Modeling) Method 25.1.3 SPICE and PSPICE Simulation Programs 25.2 Simulating Switching Power Supplies with SPICE and PSPICE General Circuit Simulation Programs 25.2.1 Overview 25.2.2 SPICE Simulation Model of Power Semiconductor Switches 25.2.3 SPICE Simulation Model of Control Circuits 25.2.4 SPICE simulation of forward PWM switching power supply 25.2.5 SPICE simulation of push-pull PWM switching power supply and optimization of compensation network parameters 25.3 Discrete time domain simulation 25.3.1 Overview 25.3.2 Numerical method to solve the state equation of piecewise linear network 25.3.3 Solve the conversion time of network topology (boundary conditions) 25.3.4 Nonlinear difference equation (large signal model) 25.3.5 Small signal model 25.3.6 Program flowchart 25.3.7 Simulation calculation example Chapter 26 Optimal design of switching power supply 26.1 Overview 26.1.1 Feasible design 26.1.2 Optimal design 26.1.3 Main performance indicators of switching power supply 26.2 Basic concepts of engineering optimization 26.2.1 Optimization design model 26.2.2 Design variables 26.2.3 Objective function 26.2.4 Constraints 26.2.5 General form of optimization mathematical model 26.2.6 Characteristics of engineering optimization design 26.3 Several issues in the application of optimization methods 26.3.1 Properties of the optimal solution 26.3.2 Selection of the initial point 26.3.3 Convergence data 26.3.4 Unification of variable scales 26.3.5 Unification of constraint value scales 26.3.6 Multi-objective optimization problems 26.4 Optimal design of DC-DC bridge switching converters 26.4.1 Optimal design of the main circuit of DC-DC half-bridge PWM switching converters 26.4.2 Mathematical model for optimal design of switch, rectifier and filter circuits 26.4.3 Mathematical model for optimal design of transformers 26.4.4 Implementation of optimal design of half-bridge PWM switching converters 26.4.5 Example of optimal design of 5V/500W output DC-DC half-bridge PWM switching converters 26.4.6 Optimal design of the main circuit of DC-DC full-bridge ZVS-PWM converters 26.5 Optimal design of single-ended flyback PWM switching converters 26.5.1 Overview of mathematical models 26.5.2 Methods for making multiple outputs equivalent to one output 26.5.3 Optimization design examples 26.6 Optimization design of compensation network for PWM switching power supply control circuit 26.6.1 Overview 26.6.2 Brief introduction to transient response characteristics of switching power supply 26.6.3 Frequency domain characteristics of switching converters 26.6.4 Small signal model of PWM switching converter 26.6.5 Mathematical model for transient optimization design 26.6.6 Calculation examples 26.7 Optimal design of compensation network for DC-DC full-bridge phase-shifted ZVS-PWM switching power supply 26.7.1 Main circuit and voltage and current waveforms 26.7.2 Small signal model of FB ZVS-PWM converter 26.7.3 Transfer function and frequency characteristics of main circuit of FB ZVS-PWM converter 26.7.4 Optimal design model for compensation network of FB ZVS-PWM switching power supply 26.7.5 Typical design examples

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21 detailed and superb analog electronics technical questions and answers: Points it Requires : 1 Type:Application DocumentsUploader:chunyangDate:2013-04-17; Introduction:21 detailed and superb analog electronics technical questions and answers

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Basic knowledge of analog circuits Kang Huaguang: Points it Requires : 2 Type:OthersUploader:玩电子的咸鱼Date:2019-11-08; Introduction:This document is a book about basic analog circuit knowledge, which is very helpful for students who are just starting to learn.

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Electronic Circuit Analysis and Design Donald A. Neamen Chinese Edition (Analog Circuit Part): Points it Requires : 2 Type:Application DocumentsUploader:xieryouDate:2013-07-03; Introduction:Most of the circuits discussed in Part 1 of \"Electronic Circuit Analysis and Design - Analog Electronic Technology\" are discrete electronic circuits, which are circuits composed of discrete resistors, capacitors and transistors. The analysis of these basic circuits gives us a preliminary understanding of the working principles and circuit characteristics of these circuits. The book introduces the concept of electronic circuit design through some designs and discussions, and various different compromises are considered in the discussion process. Part 2 of \"Electronic Circuit Analysis and Design - Analog Electronic Technology\" will gradually analyze and design more complex analog electronic circuits in depth. These more complex circuits are formed by combining and expanding the basic circuits learned in Part 1. However, most of the following content continues to analyze and design discrete circuits, because integrated circuits are composed of these discrete circuits. In this brief preface, some basic issues in the electronic design process will be discussed.

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Analog Electronic Technology Basic Courseware (Huachengying) Classic.pdf: Points it Requires : 1 Type:CourseUploader:TimsonDate:2014-03-12; Introduction:Analog Electronic Technology Basic Courseware (Huachengying) Classic.pdf

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