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100   $a20050517d2006      uy         0
101 0 $aeng
135   $aurcn|||||||||
181   $ctxt
182   $cc
183   $acr
200 10$aSwitch-mode power converters $edesign and analysis /$fKeng C. Wu
205   $a1st ed.
210   $aAmsterdam ;$aBoston $cElsevier Academic Press$dc2006
215   $a1 online resource (409 p.)
300   $aDescription based upon print version of record.
311   $a1-4933-0008-3 
311   $a0-12-088795-9 
320   $aIncludes bibliographical references (p. 385-386) and index.
327   $aFront Cover; Switch-Mode Power Converters: Design and Analysis; Copyright Page; Table of Contents; Preface; Chapter 1. Isolated Step-Down (Buck) Converter; 1.1 CCM Open-Loop Output and Duty Cycle Determination; 1.2 DCM Open-Loop Output and Duty Cycle Determination; 1.3 CCM to DCM Transition, Critical Inductance; 1.4 Gain Formula for Nonideal Operational Amplifiers; 1.5 Feedback under Voltage-Mode Control; 1.6 Voltage-Mode CCM Closed Loop; 1.7 Voltage-Mode DCM Closed Loop; 1.8 Voltage-Mode CCM Small-Signal Stability; 1.9 Current-Mode Control
327   $a1.10 CCM Current-Mode Control in a Closed-Loop Steady State 1.11 CCM Current-Mode Control Small-Signal Stability; 1.12 Output Capacitor Size and Accelerated Steady-State Analysis; 1.13 A Complete Example; 1.14 State Transition Technique; Chapter 2. Push-Pull Converter with Current-Mode Control and Slope Compensation; 2.1 Power Stage of a Center-Tapped Push-Pull Converter; 2.2 Discontinuous Conduction-Mode Operation; 2.3 Continuous Conduction-Mode Operation; Chapter 3. Nonisolated Forward Converter with Average Current-Mode Control; 3.1 Average Current Feedback; 3.2 Duty Cycle Determination
327   $a3.3 Steady-State Closed Loop 3.4 Closed-Loop Regulation and Output Sensitivity; 3.5 Small-Signal Loop Gain and Stability; 3.6 Example; 3.7 State Transition Technique; Chapter 4. Phase-Shifted Full-Bridge Converter; 4.1 Power-Stage Operation; 4.2 Current Doubler; 4.3 Steady-State Duty Cycle; 4.4 Steady-State Output Waveforms; 4.5 Steady-State Output Waveforms Example; Chapter 5. Current-Fed Push-Pull Converters; 5.1 Overlapping Continuous-Conduction Mode; 5.2 Overlapping Continuous Conduction, Steady State; 5.3 Overlapping Continuous Conduction, Example
327   $a5.4 Nonoverlapping Continuous-Conduction Mode 5.5 Load Current Sharing and Parallel Operation; 5.6 AC Small-Signal Studies Using State-Space Averaging; 5.7 State-Transition Technique; Chapter 6. Isolated Flyback Converters; 6.1 DCM Duty-Cycle Determination, Another Approach; 6.2 CCM Duty-Cycle Determination; 6.3 Critical Inductance; 6.4 Voltage-Mode DCM Closed Loop; 6.5 Voltage-Mode DCM Small-Signal Stability; 6.6 Voltage-Mode CCM Closed Loop; 6.7 Voltage-Mode CCM Small-Signal Stability; 6.8 Peak Current-Mode DCM Closed Loop; 6.9 Peak Current-Mode DCM Small-Signal Stability
327   $a6.10 Peak Current-Mode CCM Closed Loop 6.11 Peak Current-Mode CCM Small-Signal Stability; 6.12 Output Capacitor; 6.13 Accelerated Steady-State Output; 6.14 A Complete DCM Example; Chapter 7. Nonisolated Boost Converter; 7.1 Duty-Cycle Determination; 7.2 Critical Inductance; 7.3 Peak Current-Mode Closed-Loop Steady State in CCM; 7.4 Peak Current-Mode Small-Signal Stability in CCM; 7.5 Peak Current-Mode Closed-Loop Steady State in DCM; 7.6 Peak Current-Mode Small-Signal Stability in DCM; 7.7 DCM Output Capacitor Size; 7.8 CCM Output Capacitor Size; Chapter 8. Quasi-Resonant Converters
327   $a8.1 How Does It Work?
330   $aThis book introduces an innovative, highly analytical approach to symbolic, closed-form solutions for switched-mode power converter circuits. This is a highly relevant topic to power electronics students and professionals who are involved in the design and analysis of electrical power converters. The author uses extensive equations to explain how solid-state switches convert electrical voltages from one level to another, so that electronic devices (e.g., audio speakers, CD players, DVD players, etc.) can use different voltages more effectively to perform their various functions. Most existing
606   $aElectric current converters
606   $aSwitching power supplies
615  0$aElectric current converters.
615  0$aSwitching power supplies.
676   $a621.31/7
676   $a621.317
700   $aWu$b Keng C.$f1948-$0557142
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910826500703321
996   $aSwitch-mode power converters$94073553
997   $aUNINA