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100   $a20140413h20142014  uy             0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 10$aEnhanced phase-locked loop structures for power and energy applications /$fMasoud Karimi-Ghartemani
210  1$aHoboken, New Jersey :$cJohn Wiley & Sons,$d2014.
210  4$dİ2014
215   $a1 online resource (230 p.)
225 1 $aIEEE Press Series on Microelectronic Systems
300   $aDescription based upon print version of record.
311   $a1-118-79518-0 
311   $a1-118-79502-4 
320   $aIncludes bibliographical references and index.
327   $aENHANCED PHASE-LOCKED LOOP STRUCTURES FOR POWER AND ENERGY APPLICATIONS; Copyright; BRIEF CONTENTS; CONTENTS; PREFACE; ACKNOWLEDGMENTS; ACRONYMS; SYMBOLS; INTRODUCTION; I PLL STRUCTURES FOR SINGLE-PHASEAPPLICATIONS; 1 PLL Basics and Standard Structure; 1.1 Standard PLL Structure; 1.2 Approximate Linear Model; 1.3 Loop Filter Design; 1.4 Remarks; 1.5 Numerical Results; 1.6 Summary and Conclusion; Problems; 2 Enhanced Phase-Locked Loop; 2.1 Structure of EPLL; 2.2 Removal of Double-Frequency Error; 2.3 Linear Analysis; 2.4 Derivation of EPLL Using Gradient Method; 2.5 Pseudolinear EPLL
327   $a2.6 Derivation of PL-EPLL from Newton Approach2.7 Linear Time Invariant EPLL; 2.8 LTI-EPLL as a Resonant Controller; 2.9 Extension of LTI-EPLL as a General Transfer Function; 2.10 Resonant Controller with Phase Compensation; 2.11 VCO-Less Representation of EPLL; 2.12 VCO-Less EPLL versus ANF and SOGI-FLL; 2.13 EPLL and Droop Control Method; 2.14 Adjustment of EPLL Parameters; 2.15 Numerical Results; 2.16 Summary and Conclusion; Problems; 3 EPLL Extensions and Modifications; 3.1 Prefiltering and Postfiltering; 3.2 In-Loop Filters and Concept of Windowing; 3.3 Design of W-EPLL
327   $a3.4 Estimation and Rejection of DC Component3.5 Estimation and Rejection of Harmonics; 3.6 Mitigation of Multiple Harmonics Using SingleBand-Stop Filter; 3.7 Estimation and Rejection of Interharmonics; 3.8 EPLL with Generalized Filtering; 3.9 Soft Start and Problem of Phase Jumps; 3.10 Summary and Conclusion; Problems; 4 Digital Implementation of EPLL; 4.1 First-Order Digitization; 4.2 LTI-EPLL Resonant Controller; 4.3 Robustness in Low Sampling Frequency Applications; 4.4 Robustness in Fixed-Point, High Sampling FrequencyApplications; 4.5 Summary and Conclusion; Problems
327   $a5 Integrated Synchronization and Control5.1 Brief Review of Synronization/Control Methods; 5.2 ISC Method; 5.3 Stability Analysis of ISC Method; 5.4 Design Algorithm for ISC Method; 5.5 Comments on Reference Values; 5.6 Power Quality Issues; 5.7 Soft Start Process; 5.8 LCL Output Filter; 5.9 Sensitivity Analysis; 5.10 Numerical Results; 5.11 Summary and Conclusion; Problems; II PLL STRUCTURES FOR THREE-PHASEAPPLICATIONS; 6 Synchronous Reference Frame PLL; 6.1 Structure of SRF-PLL; 6.2 Linear Model and Design; 6.3 Alternative Representation of SRF-PLL; 6.4 SRF-PLL Operation in Stationary Frame
327   $a6.5 Single-Phase SRF-PLL6.6 Correspondence between SRF-PLL and Single-PhaseEPLL; 6.7 Impact of Unbalance, DC, and Harmonics on SRF-PLL; 6.8 Numerical Results; 6.9 Summary and Conclusion; Problems; 7 Three-Phase EPLL-I; 7.1 Structure of Three-Phase EPLL-I; 7.2 Relationship between 3EPLL-I and SRF-PLL; 7.3 3EPLL-I in Stationary Frame; 7.4 Mathematical Derivation of 3EPLL-I; 7.5 LTI-3EPLL-I; 7.6 VCO-Less Representation of 3EPLL-I; 7.7 Design Guidelines for 3EPLL-I; 7.8 Numerical Results; 7.9 Summary and Conclusion; Problems; 8 Three-Phase EPLL-II; 8.1 Structure of Three-Phase EPLL-II
327   $a8.2 Derivation of Three-Phase EPLL-II
330   $a"Many excellent books covering phase-locked loops (PLLs) have been published; however, there is practically no book that covers the specifics of PLLs as employed in power systems. The usefulness for such a book fills an immediate need. Existing books cover the type of PLLs used in electronics, communications and instrumentation. Over the past decade or so, many new PLL structures have been developed to address the new requirements in modern power systems. The enhanced phase-locked loop (EPLL) is arguably the most widely accepted structure developed to address power system requirements. It is now a mature concept and has been developed in multiple forms and to address many applications. Due to the structural differences as well as the differences in applications requirements that exist between the "PLL" and the "EPLL", existing books do not offer sufficient material to understand and employ the EPLL. The aim of the proposed book is to fill this gap and to provide a book that clearly, and in simple language, explains the EPLL and reviews its multiple forms and variety of its applications"--$cProvided by publisher.
330   $a"Offers comprehensive coverage of several phased-locked loop (PLL) architectures and numerous applications of those in power engineering"--$cProvided by publisher.
410  0$aIEEE Press series on microelectronic systems.
606   $aPhase-locked loops
606   $aElectric power systems$xEquipment and supplies
606   $aPower electronics
615  0$aPhase-locked loops.
615  0$aElectric power systems$xEquipment and supplies.
615  0$aPower electronics.
676   $a621.31/7
686   $aTEC008010$2bisacsh
700   $aKarimi-Ghartema$b Masoud$0895732
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910132218303321
996   $aEnhanced phase-locked loop structures for power and energy applications$92001008
997   $aUNINA