Optimal Design of Switching Power Supply

A contemporary evaluation of switching power design methods with real world applications Written by a leading author renowned in his field Focuses on switching power supply design, manufacture and debugging Switching power supplies have relevance for contemporary applications including mobile phone chargers, laptops and PCs Based on the authors? successful Switching Power Optimized Design 2nd Edition (in Chinese) Highly illustrated with design examples of real world applications INDICE: Chapter 1  Overview on Switching Mode Power Supply (SMPS)1.1  Classification of Integrated Regulated Power Supply1.2  Characteristics of SMPS1.3  New Development Trend of SMPS1.4  Basic Principles of SMPS1.5  Control Mode Type of SMPS1.6  Working Mode of SMPS1.7  Feedback Type of SMPS1.8  Load Characteristics of SMPSChapter 2  New Technology and Its Application of SMPS2.1  Single–chip Integration of SMPS2.2  Computer–based SMPS Design2.3  Internal Protective Circuit of SMPS2.4  Synchronous Rectification (SR) Technology2.5  Active Clamp Technology2.6  Magnetic Amplifier Regulator Technology2.7  Programmable Voltage Regulator Technology2.8  Digital Power Supply System2.9  Energy–saving and Environment–friendly Technology of SMPSChapter 3  Topology of DC/DC Converter3.1  Topology of DC/DC Converter3.2  Basic Principle of Buck Converter3.3  Basic Principle of Boost Converter3.4  Basic Principle of Buck–Boost Converter3.5  Basic Principle of Charge Pump Converter3.6  Basic Principle of SEPIC3.7  Basic Principle of Flyback Converter3.8  Basic Principle of Forward Converter3.9  Basic Principle of Push–Pull Converter3.10  Basic Principle of Half/Full Bridge Converter3.11  Basic Principle of Soft Switching Converter3.12  Basic Principle of Half–Bridge LLC Resonant Converter3.13  Basic Principle of 2 Switch Forward ConverterChapter 4  Method for Selecting Key Peripheral Components of SMPS4.1  Selection Method of Fixed Resistor4.2  Selection Method of Capacitor4.3  Inductor Characteristics and Selection Method of Magnetic Bead4.4  Selection Method of EMI Filter4.5  Selection Method of Input Bridge Rectifier4.6  Selection Method of Output Rectifier4.7  Selection Method of Transient Voltage Suppressor (TVS)4.8  Selection Method of Power Switching Tube4.9  Selection Method of Optical Coupler4.10  Selection Method of Adjustable Precision Shunt Regulator4.11  Selection Method of SMPS Protection ElementsChapter 5  Power Factor Correction Circuit Design of SMPS5.1  Brief Introduction to Power Factor Correction (PFC)5.2  Basic Principle of Passive PFC Circuit5.3  Design Examples of Passive PFC Circuit5.4  Basic Principle of Active PFC Circuit5.5  Design Examples of Active PFC Circuit5.6  Principle and Application of High–Power PFC5.7  Measures to Suppress PFC Electromagnetic Interference5.8  PFC Configuration SchemeChapter 6  Design of High–Frequency Transformer6.1  Selection Method of Magnetic Cores According to the Empirical Formula or Output Power Table6.2  Waveform Parameters of the High–Frequency Transformer Circuit6.3  AP Method Based Formula Derivation of Selecting High–Frequency Transformer Magnetic Core6.4  Design of Flyback High–Frequency Transformer6.5  Design of Forward High–Frequency Transformer6.6  Loss of High–Frequency TransformerChapter 7  Examples of SMPS Optimization Design7.1  Multi–Output SMPS Design7.2  Methods to Improve the Cross Load Regulation of Multi–Output SMPS7.3  Design of PC SMPS with Magnetic Amplifier7.4  Design of Synchronous Rectification DC/DC Converter7.5  Design of SMPS for Peak–Power–Output Audio Power Amplifier7.6  Design of Industrial Control Power Supply Based on Voltage–Doubling Rectifier7.7  Design of Industrial Control Power Supply Based on Suspension High–Voltage Constant Current Source7.8  Design of StackFETM Technology Based Micro SMPS7.9  Design of Power Supply for the Digital TV Set–Top Box7.10  Design of Mobile Phone Charger with USB InterfaceChapter 8  Key Design Points of SMPS8.1  SMPS Design Requirements8.2  Design of High–Efficiency SMPS8.3  Methods of Reducing No–Load and Standby Power Consumption of SMPS8.4  Stability Design of Optocoupler Feedback Control Loop8.5  SMPS Layout and Wiring8.6  Design of Constant Voltage/Current SMPS8.7  Design of Precision Constant Voltage/Current SMPS8.8  Design of Remote Turn–off Circuit for SMPS8.9  Typical Application and Printed Circuit Design of New Single–Chip SMPS8.10  Electromagnetic Interference Waveform Analysis and Safety Code Design of SMPS8.11  Radiator Design of Single–Chip SMPS8.12  Radiator Design of Power Switching Tube (MOSFET)8.13  Common Troubleshooting Methods of SMPSChapter 9  SMPS Testing Technology9.1  Parameter Testing of SMPS9.2  Performance Testing of SMPS9.3  SMPS Measurement Skills9.4  Accurate Measurement Method of Duty Ratio9.5  Method to Detect the Magnetic Saturation of High–Frequency Transformer with Oscilloscope9.6  Digital Online Current/Resistance Meter9.7  Electromagnetic Compatibility Measurement of SMPS9.8  Waveform Test and Analysis of SMPSChapter 10  Protection and Monitoring Circuit Design of SMPS10.1  Design of Drain Clamp Protection Circuit10.2  Overvoltage Protection Circuit Constituted by Discrete Components10.3  Application of Integrated Overvoltage Protector10.4  Design of Undervoltage Protection Circuit10.5  Design of Overcurrent and Overpower Protection Circuit10.6  Design of Soft–Start Circuit10.7  Mains Voltage Monitor10.8  Transient Interference and Audio Noise Suppression Technology of SMPS10.9  Design of Overheating Protection Component and Cooling Control SystemReferences

• ISBN: 978-1-118-79090-8
• Editorial: Wiley–Blackwell
• Encuadernacion: Cartoné
• Páginas: 440
• Fecha Publicación: 30/07/2015
• Nº Volúmenes: 1
• Idioma: Inglés