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Affiner la recherche Interroger des sources externesPower system stability Vol.1 / Edward Wilson Kimbark
Titre : Power system stability Vol.1 : elements of stability calculations Type de document : texte imprimé Auteurs : Edward Wilson Kimbark, Auteur Editeur : New York : IEEE Press /John Wiley & Sons,Inc.,Publication Année de publication : 1995 Collection : IEEE Press Power System Engineering Series Importance : 355 p. Présentation : couv. ill. en coul., ill. Format : 23 cm. ISBN/ISSN/EAN : 978-0-7803-1135-0 Langues : Anglais (eng) Catégories : ELECTROTECHNIQUE Index. décimale : 10-04 Réseaux et protection Résumé : Power System Stability, Volumes I, II, III is a classic reference for power-system engineers, now reissued together as a set. Volume I, Elements of Stability Calculations, covers the elements of stability, principal affecting factors, and applications on power systems. Volume II, Power Circuit Breakers and Protective Relays features in-depth information on organization, materials, actions, and conditions as they relate to power system stability. Volume III, Synchronous Machines, details the more advanced calculations required in special circumstances that demand a higher level of accuracy than the simplified calculations presented in Volume I can provide. Note de contenu : Contents:
Chapter1: The stability problem
Chapter2: The swing equation and its solution
Chapter3: Solution of networks
Chapter4: The equal-area criterion for stability
Chapter5: Further consideration of the two -machine system
Chapter6: Solution of faulted three-phase networks
Chapter7: Typical stability studiesPower system stability Vol.1 : elements of stability calculations [texte imprimé] / Edward Wilson Kimbark, Auteur . - New York : IEEE Press /John Wiley & Sons,Inc.,Publication, 1995 . - 355 p. : couv. ill. en coul., ill. ; 23 cm.. - (IEEE Press Power System Engineering Series) .
ISBN : 978-0-7803-1135-0
Langues : Anglais (eng)
Catégories : ELECTROTECHNIQUE Index. décimale : 10-04 Réseaux et protection Résumé : Power System Stability, Volumes I, II, III is a classic reference for power-system engineers, now reissued together as a set. Volume I, Elements of Stability Calculations, covers the elements of stability, principal affecting factors, and applications on power systems. Volume II, Power Circuit Breakers and Protective Relays features in-depth information on organization, materials, actions, and conditions as they relate to power system stability. Volume III, Synchronous Machines, details the more advanced calculations required in special circumstances that demand a higher level of accuracy than the simplified calculations presented in Volume I can provide. Note de contenu : Contents:
Chapter1: The stability problem
Chapter2: The swing equation and its solution
Chapter3: Solution of networks
Chapter4: The equal-area criterion for stability
Chapter5: Further consideration of the two -machine system
Chapter6: Solution of faulted three-phase networks
Chapter7: Typical stability studiesExemplaires
Code-barres Cote Support Localisation Section Disponibilité N.Inventaire 422 10-04-07 Livre Bibliothèque de Génie Electrique- USTO Documentaires Exclu du prêt 422
Titre : Pulse width modulation for power converters : principles and practice Type de document : texte imprimé Auteurs : D. Grahame Holmes, Auteur ; Thomas A. Lipo, Auteur Editeur : New York : IEEE Press /John Wiley & Sons,Inc.,Publication Année de publication : 2003 Collection : IEEE Press Power System Engineering Series Importance : 724 p. Présentation : couv. ill. en coul., ill. Format : 24 cm. ISBN/ISSN/EAN : 978-0-471-20814-3 Langues : Anglais (eng) Catégories : ELECTROTECHNIQUE Index. décimale : 10-05 Electronique de puissance et industrielle Résumé : An integrated and comprehensive theory of PWM
The selection of the best algorithm for optimum pulse width modulation is an important process that can result in improved converter efficiency, better load (motor) efficiency, and reduced electromagnetic interference. However, the identification of the best approach is a complex process requiring extensive mathematical manipulation.
Pulse Width Modulation for Power Converters: Principles and Practice is the first single-volume resource written to help researchers in the field attain a working knowledge of the subject. The authors bring together today's seemingly diverse approaches into a single integrated and comprehensive theory of modulation.
The book provides a generalized approach to the fundamentals of PWM, looking at:
Active switch pulse width determination
Active switch pulse placement within a switching period
Active switch pulse sequence between phase legs and across switching periods
The main benefit of this generalized concept is that once the common threads are identified, the selection of a modulation strategy for any converter topology becomes immediately clear, leaving only secondary factors, such as practical performance, cost, and difficulty of implementation to consider. Additionally, it allows the performance of any particular converter topology and PWM strategy to be quickly and easily identified without complex and time-consuming analysis. Pulse Width Modulation for Power Converters: Principles and Practice enables the reader to achieve optimum PWM results for any application.Note de contenu : Contents:
Chapter 1: Introduction to Power Electronic Converters.
1.1 Basic Converter Topologies.
1.2 Voltage Source/Stiff Inverters.
1.3 Switching Function Representation of Three-Phase Converters.
1.4 Output Voltage Control.
1.5 Current Source/Stiff Inverters.
1.6 Concept of a Space Vector.
1.7 Three-Level Inverters.
1.8 Multilevel Inverter Topologies.
Chapter 2: Harmonic Distortion.
2.1 Harmonic Voltage Distortion Factor.
2.2 Harmonic Current Distortion Factor.
2.3 Harmonic Distortion Factors for Three-Phase Inverters.
2.4 Choice of Performance Indicator.
2.5 WTHD of Three-Level Inverter.
2.6 The Induction Motor Load.
2.7 Harmonic Distortion Weighting Factors for Induction Motor Load.
2.8 Example Calculation of Harmonic Losses.
2.9 WTHD Normalization for PWM Inverter Supply.
Chapter 3: Modulation of One Inverter Phase Leg.
3.1 Fundamental Concepts of PWM.
3.2 Evaluation of PWM Schemes.
3.3 Double Fourier Integral Analysis of a Two-Level Pulse Width-Modulated Waveform.
3.4 Naturally Sampled Pulse Width Modulation.
3.5 PWM Analysis by Duty Cycle Variation.
3.6 Regular Sampled Pulse Width Modulation.
3.7 "Direct" Modulation.
3.8 Integer versus Non-Integer Frequency Ratios.
3.9 Review of PWM Variations.
Chapter 4: Modulation of Single-Phase Voltage Source Inverters.
4.1 Topology of a Single-Phase Inverter.
4.2 Three-Level Modulation of a Single-Phase Inverter.
4.3 Analytic Calculation of Harmonic Losses.
4.4 Sideband Modulation.
4.5 Switched Pulse Position.
4.6 Switched Pulse Sequence.
Chapter 5: Modulation of Three-Phase Voltage Source Inverters.
5.1 Topology of a Three-Phase Inverter (VSI).
5.2 Three-Phase Modulation with Sinusoidal References.
5.3 Third-Harmonic Reference Injection.
5.4 Analytic Calculation of Harmonic Losses.
5.5 Discontinuous Modulation Strategies.
5.6 Triplen Carrier Ratios and Subharmonics.
Chapter 6: Zero Space Vector Placement Modulation Strategies.
6.1 Space Vector Modulation.
6.2 Phase Leg References for Space Vector Modulation.
6.3 Naturally Sampled SVM.
6.4 Analytical Solution for SVM.
6.5 Harmonic Losses for SVM.
6.6 Placement of the Zero Space Vector.
6.7 Discontinuous Modulation.
6.8 Phase Leg References for Discontinuous PWM.
6.9 Analytical Solutions for Discontinuous PWM.
6.10 Comparison of Harmonic Performance.
6.11 Harmonic Losses for Discontinuous PWM.
6.12 Single-Edge SVM.
6.13 Switched Pulse Sequence.
Chapter 7: Modulation of Current Source Inverters.
7.1 Three-Phase Modulators as State Machines.
7.2 Naturally Sampled CSI Space Vector Modulator.
7.3 Experimental Confirmation.
Chapter 8: Overmodulation of an Inverter.
8.1 The Overmodulation Region.
8.2 Naturally Sampled Overmodulation of One Phase Leg of an Inverter.
8.3 Regular Sampled Overmodulation of One Phase Leg of an Inverter.
8.4 Naturally Sampled Overmodulation of Single- and Three-Phase Inverters.
8.5 PWM Controller Gain during Overmodulation.
8.6 Space Vector Approach to Overmodulation.
Chapter 9: Programmed Modulation Strategies.
9.1 Optimized Space Vector Modulation.
9.2 Harmonic Elimination PWM.
9.3 Performance Index for Optimality.
9.4 Optimum PWM.
9.5 Minimum-Loss PWM.
Chapter 10: Programmed Modulation of Multilevel Converters.
10.1 Multilevel Converter Alternatives.
10.2 Block Switching Approaches to Voltage Control.
10.3 Harmonic Elimination Applied to Multilevel Inverters.
10.4 Minimum Harmonic Distortion.
Chapter 11: Carrier-Based PWM of Multilevel Inverters.
11.1 PWM of Cascaded Single-Phase H-Bridges.
11.2 Overmodulation of Cascaded H-Bridges.
11.3 PWM Alternatives for Diode-Clamped Multilevel Inverters.
11.4 Three-Level Naturally Sampled PD PWM.
11.5 Three-Level Naturally Sampled APOD or POD PWM.
11.6 Overmodulation of Three-Level Inverters.
11.7 Five-Level PWM for Diode-Clamped Inverters.
11.8 PWM of Higher Level Inverters.
11.9 Equivalent PD PWM for Cascaded Inverters.
11.10 Hybrid Multilevel Inverter.
11.11 Equivalent PD PWM for a Hybrid Inverter.
11.12 Third-Harmonic Injection for Multilevel Inverters.
11.13 Operation of a Multilevel Inverter with a Variable Modulation Index.
Chapter 12: Space Vector PWM for Multilevel Converters.
12.1 Optimized Space Vector Sequences.
12.2 Modulator for Selecting Switching States.
12.3 Decomposition Method.
12.4 Hexagonal Coordinate System.
12.5 Optimal Space Vector Position within a Switching Period.
12.6 Comparison of Space Vector PWM to Carrier-Based PWM.
12.7 Discontinuous Modulation in Multilevel Inverters.
Chapter 13: Implementation of a Modulation Controller.
13.1 Overview of a Power Electronic Conversion System.
13.2 Elements of a PWM Converter System.
13.3 Hardware Implementation of the PWM Process.
13.4 PWM Software Implementation.
Chapter 14: Continuing Developments in Modulation.
14.1 Random Pulse Width Modulation.
14.2 PWM Rectifier with Voltage Unbalance.
14.3 Common Mode Elimination.
14.4 Four Phase Leg Inverter Modulation.
14.5 Effect of Minimum Pulse Width.
Appendix 1: Fourier Series Representation of a Double Variable Controlled Waveform.
Appendix 2: Jacobi-Anger and Bessel Function Relationships.
A2.1 Jacobi-Anger Expansions.
A2.2 Bessel Function Integral Relationships.
Appendix 3: Three-Phase and Half-Cycle Symmetry Relationships.
Appendix 4: Overmodulation of a Single-Phase Leg.
A4.1 Naturally Sampled Double-Edge PWM.
A4.2 Symmetric Regular Sampled Double-Edge PWM.9
A4.3 Asymmetric Regular Sampled Double-Edge PWM.
Appendix 5: Numeric Integration of a Double Fourier Series Representation of a Switched Waveform.
A5.1 Formulation of the Double Fourier Integral.
A5.2 Analytical Solution of the Inner Integral.
A5.3 Numeric Integration of the Outer Integral.
14.6 PWM Dead-Time Compensation.Pulse width modulation for power converters : principles and practice [texte imprimé] / D. Grahame Holmes, Auteur ; Thomas A. Lipo, Auteur . - New York : IEEE Press /John Wiley & Sons,Inc.,Publication, 2003 . - 724 p. : couv. ill. en coul., ill. ; 24 cm.. - (IEEE Press Power System Engineering Series) .
ISBN : 978-0-471-20814-3
Langues : Anglais (eng)
Catégories : ELECTROTECHNIQUE Index. décimale : 10-05 Electronique de puissance et industrielle Résumé : An integrated and comprehensive theory of PWM
The selection of the best algorithm for optimum pulse width modulation is an important process that can result in improved converter efficiency, better load (motor) efficiency, and reduced electromagnetic interference. However, the identification of the best approach is a complex process requiring extensive mathematical manipulation.
Pulse Width Modulation for Power Converters: Principles and Practice is the first single-volume resource written to help researchers in the field attain a working knowledge of the subject. The authors bring together today's seemingly diverse approaches into a single integrated and comprehensive theory of modulation.
The book provides a generalized approach to the fundamentals of PWM, looking at:
Active switch pulse width determination
Active switch pulse placement within a switching period
Active switch pulse sequence between phase legs and across switching periods
The main benefit of this generalized concept is that once the common threads are identified, the selection of a modulation strategy for any converter topology becomes immediately clear, leaving only secondary factors, such as practical performance, cost, and difficulty of implementation to consider. Additionally, it allows the performance of any particular converter topology and PWM strategy to be quickly and easily identified without complex and time-consuming analysis. Pulse Width Modulation for Power Converters: Principles and Practice enables the reader to achieve optimum PWM results for any application.Note de contenu : Contents:
Chapter 1: Introduction to Power Electronic Converters.
1.1 Basic Converter Topologies.
1.2 Voltage Source/Stiff Inverters.
1.3 Switching Function Representation of Three-Phase Converters.
1.4 Output Voltage Control.
1.5 Current Source/Stiff Inverters.
1.6 Concept of a Space Vector.
1.7 Three-Level Inverters.
1.8 Multilevel Inverter Topologies.
Chapter 2: Harmonic Distortion.
2.1 Harmonic Voltage Distortion Factor.
2.2 Harmonic Current Distortion Factor.
2.3 Harmonic Distortion Factors for Three-Phase Inverters.
2.4 Choice of Performance Indicator.
2.5 WTHD of Three-Level Inverter.
2.6 The Induction Motor Load.
2.7 Harmonic Distortion Weighting Factors for Induction Motor Load.
2.8 Example Calculation of Harmonic Losses.
2.9 WTHD Normalization for PWM Inverter Supply.
Chapter 3: Modulation of One Inverter Phase Leg.
3.1 Fundamental Concepts of PWM.
3.2 Evaluation of PWM Schemes.
3.3 Double Fourier Integral Analysis of a Two-Level Pulse Width-Modulated Waveform.
3.4 Naturally Sampled Pulse Width Modulation.
3.5 PWM Analysis by Duty Cycle Variation.
3.6 Regular Sampled Pulse Width Modulation.
3.7 "Direct" Modulation.
3.8 Integer versus Non-Integer Frequency Ratios.
3.9 Review of PWM Variations.
Chapter 4: Modulation of Single-Phase Voltage Source Inverters.
4.1 Topology of a Single-Phase Inverter.
4.2 Three-Level Modulation of a Single-Phase Inverter.
4.3 Analytic Calculation of Harmonic Losses.
4.4 Sideband Modulation.
4.5 Switched Pulse Position.
4.6 Switched Pulse Sequence.
Chapter 5: Modulation of Three-Phase Voltage Source Inverters.
5.1 Topology of a Three-Phase Inverter (VSI).
5.2 Three-Phase Modulation with Sinusoidal References.
5.3 Third-Harmonic Reference Injection.
5.4 Analytic Calculation of Harmonic Losses.
5.5 Discontinuous Modulation Strategies.
5.6 Triplen Carrier Ratios and Subharmonics.
Chapter 6: Zero Space Vector Placement Modulation Strategies.
6.1 Space Vector Modulation.
6.2 Phase Leg References for Space Vector Modulation.
6.3 Naturally Sampled SVM.
6.4 Analytical Solution for SVM.
6.5 Harmonic Losses for SVM.
6.6 Placement of the Zero Space Vector.
6.7 Discontinuous Modulation.
6.8 Phase Leg References for Discontinuous PWM.
6.9 Analytical Solutions for Discontinuous PWM.
6.10 Comparison of Harmonic Performance.
6.11 Harmonic Losses for Discontinuous PWM.
6.12 Single-Edge SVM.
6.13 Switched Pulse Sequence.
Chapter 7: Modulation of Current Source Inverters.
7.1 Three-Phase Modulators as State Machines.
7.2 Naturally Sampled CSI Space Vector Modulator.
7.3 Experimental Confirmation.
Chapter 8: Overmodulation of an Inverter.
8.1 The Overmodulation Region.
8.2 Naturally Sampled Overmodulation of One Phase Leg of an Inverter.
8.3 Regular Sampled Overmodulation of One Phase Leg of an Inverter.
8.4 Naturally Sampled Overmodulation of Single- and Three-Phase Inverters.
8.5 PWM Controller Gain during Overmodulation.
8.6 Space Vector Approach to Overmodulation.
Chapter 9: Programmed Modulation Strategies.
9.1 Optimized Space Vector Modulation.
9.2 Harmonic Elimination PWM.
9.3 Performance Index for Optimality.
9.4 Optimum PWM.
9.5 Minimum-Loss PWM.
Chapter 10: Programmed Modulation of Multilevel Converters.
10.1 Multilevel Converter Alternatives.
10.2 Block Switching Approaches to Voltage Control.
10.3 Harmonic Elimination Applied to Multilevel Inverters.
10.4 Minimum Harmonic Distortion.
Chapter 11: Carrier-Based PWM of Multilevel Inverters.
11.1 PWM of Cascaded Single-Phase H-Bridges.
11.2 Overmodulation of Cascaded H-Bridges.
11.3 PWM Alternatives for Diode-Clamped Multilevel Inverters.
11.4 Three-Level Naturally Sampled PD PWM.
11.5 Three-Level Naturally Sampled APOD or POD PWM.
11.6 Overmodulation of Three-Level Inverters.
11.7 Five-Level PWM for Diode-Clamped Inverters.
11.8 PWM of Higher Level Inverters.
11.9 Equivalent PD PWM for Cascaded Inverters.
11.10 Hybrid Multilevel Inverter.
11.11 Equivalent PD PWM for a Hybrid Inverter.
11.12 Third-Harmonic Injection for Multilevel Inverters.
11.13 Operation of a Multilevel Inverter with a Variable Modulation Index.
Chapter 12: Space Vector PWM for Multilevel Converters.
12.1 Optimized Space Vector Sequences.
12.2 Modulator for Selecting Switching States.
12.3 Decomposition Method.
12.4 Hexagonal Coordinate System.
12.5 Optimal Space Vector Position within a Switching Period.
12.6 Comparison of Space Vector PWM to Carrier-Based PWM.
12.7 Discontinuous Modulation in Multilevel Inverters.
Chapter 13: Implementation of a Modulation Controller.
13.1 Overview of a Power Electronic Conversion System.
13.2 Elements of a PWM Converter System.
13.3 Hardware Implementation of the PWM Process.
13.4 PWM Software Implementation.
Chapter 14: Continuing Developments in Modulation.
14.1 Random Pulse Width Modulation.
14.2 PWM Rectifier with Voltage Unbalance.
14.3 Common Mode Elimination.
14.4 Four Phase Leg Inverter Modulation.
14.5 Effect of Minimum Pulse Width.
Appendix 1: Fourier Series Representation of a Double Variable Controlled Waveform.
Appendix 2: Jacobi-Anger and Bessel Function Relationships.
A2.1 Jacobi-Anger Expansions.
A2.2 Bessel Function Integral Relationships.
Appendix 3: Three-Phase and Half-Cycle Symmetry Relationships.
Appendix 4: Overmodulation of a Single-Phase Leg.
A4.1 Naturally Sampled Double-Edge PWM.
A4.2 Symmetric Regular Sampled Double-Edge PWM.9
A4.3 Asymmetric Regular Sampled Double-Edge PWM.
Appendix 5: Numeric Integration of a Double Fourier Series Representation of a Switched Waveform.
A5.1 Formulation of the Double Fourier Integral.
A5.2 Analytical Solution of the Inner Integral.
A5.3 Numeric Integration of the Outer Integral.
14.6 PWM Dead-Time Compensation.Exemplaires
Code-barres Cote Support Localisation Section Disponibilité aucun exemplaire
Titre : Understanding FACTS : concepts and Technology of Flexible AC Transmission Systems Type de document : texte imprimé Auteurs : Narain G. Hingorani, Auteur ; Laszlo Gyugyi, Auteur Editeur : New York : IEEE Press /John Wiley & Sons,Inc.,Publication Année de publication : 1999 Importance : 428 p. Présentation : couv. ill. en coul., ill. Format : 25,9 cm. ISBN/ISSN/EAN : 978-0-7803-3455-7 Langues : Anglais (eng) Catégories : ELECTROTECHNIQUE Index. décimale : 10-05 Electronique de puissance et industrielle Résumé : Electrical Engineering Understanding FACTS Concepts and Technology of Flexible AC Transmission Systems The Flexible AC Transmission System (FACTS) a new technology based on power electronics offers an opportunity to enhance controllability, stability, and power transfer capability of ac transmission systems. Pioneers in FACTS and leading world experts in power electronics applications, Narain G. Hingorani and Laszlo Gyugyi, have teamed together to bring you the definitive book on FACTS technology. Drs. Hingorani and Gyugyi present a practical approach to FACTS that will enable electrical engineers working in the power industry to understand the principles underlying this advanced system. Understanding FACTS will enhance your expertise in equipment specifications and engineering design, and will offer you an informed view of the future of power electronics in ac transmission systems. This comprehensive reference book provides in–depth discussions on:
Power semiconductor devices
Voltage–sourced and current–sourced converters
Specific FACTS Controllers, including SVC, STATCOM, TCSC, SSSC, UPFC, IPFC plus voltage regulators, phase shifters, and special Controllers with a detailed comparison of their performance attributes
Major FACTS applications in the U.S.
Understanding FACTS is an authoritative resource that is essential reading for electrical engineers who want to stay on the cusp of the power electronics revolution.Note de contenu : Table of Contents:
CHAPTER 1 FACTS Concept and General System Considerations
1.1 Transmission Interconnections
1.2 Flow of Power in an AC System
1.3 What Limits the Loading Capability?
1.4 Power Flow and Dynamic Stability Considerations of a Transmission Interconnection
1.5 Relative Importance of Controllable Parameters
1.6 Basic Types of FACTS Controllers
1.7 Brief Description and Definitions of FACTS Controllers
1.8 Checklist of Possible Benefits from FACTS Technology
1.9 In Perspective: HVDC or FACTS
CHAPTER 2 Power Semiconductor Devices
2.1 Perspective on Power Devices
2.2 Principal High-Power Device Characteristics and Requirements
2.3 Power Device Material
2.4 Diode (Pn Junction)
2.5 Transistor
2.6 Thyristor (without Turn-Off Capability)
2.7 Gate Turn-Off Thyristor (GTO)
2.8 MOS Turn-Off Thyristor (MTO)
2.9 Emitter Turn-Off Thyristor
2.10 Integrated Gate-Commutated Thyristor (GCT and IGCT)
2.11 Insulated Gate Bipolar Transistor (IGBT)
2.12 MOS-Controlled Thyristor (MCT)
CHAPTER 3 Voltage-Sourced Converters
3.1 Basic Concept of Voltage-Sourced Converters
3.2 Single-Phase Full-Wave Bridge Converter Operation
3.3 Single Phase-Leg Operation
3.4 Square-Wave Voltage Harmonics for a Single-Phase Bridge
3.5 Three-Phase Full-Wave Bridge Converter
3.6 Sequence of Valve Conduction Process in Each Phase-Leg
3.7 Transformer Connections for 12-Pulse Operation
3.8 24- and 48-Pulse Operation
3.9 Three-Level Voltage-Sourced Converter
3.10 Pulse-Width Modulation (PWM) Converter
3.11 Generalized Technique of Harmonic Elimination and Voltage Control
3.12 Converter Rating—General Comments
CHAPTER 4 Self- and Line-Commutated Current-Sourced Converters
4.1 Basic Concept of Current-Sourced Converters
4.2 Three-Phase Full-Wave Diode Rectifier
4.3 Thyristor-Based Converter (With Gate Turn-On but Without Gate Turn-Off)
4.4 Current-Sourced Converter with Turn-Off Devices (Current Stiff Converter)
4.5 Current-Sourced Versus Voltage-Sourced Converters
CHAPTER 5 Static Shunt Compensators: SVC and STATCOM
5.1 Objectives of Shunt Compensation
5.2 Methods of Controllable Var Generation
5.3 Static Var Compensators: SVC and STATCOM
5.4 Comparison Between STATCOM and SVC
5.5 Static Var Systems
CHAPTER 6 Static Series Compensators: GCSC, TSSC, TCSC, and SSSC
6.1 Objectives of Series Compensation
6.2 Variable Impedance Type Series Compensators
6.3 Switching Converter Type Series Compensators
6.4 External (System) Control for Series Reactive Compensators
6.5 Summary of Characteristics and Features
CHAPTER 7 Static Voltage and Phase Angle Regulators: TCVR and TCPAR
7.1 Objectives of Voltage and Phase Angle Regulators
7.2 Approaches to Thyristor-Controlled Voltage and Phase Angle Regulators (TCVRs and TCPARs)
7.3 Switching Converter-Based Voltage and Phase Angle Regulators
7.4 Hybrid Phase Angle Regulators
CHAPTER 8 Combined Compensators: Unified Power Flow Controller (UPFC) and Interline Power Flow Controller (IPFC)
8.1 Introduction
8.2 The Unified Power Flow Controller
8.3 The Interline Power Flow Controller (IPFC)
8.4 Generalized and Multifunctional FACTS Controllers
CHAPTER 9 Special Purpose Facts Controllers: NGH-SSR Damping Scheme and Thyristor-Controlled Braking Resistor
9.1 Subsynchronous Resonance
9.2 NGH-SSR Damping Scheme
9.3 Thyristor-Controlled Braking Resistor (TCBR)
CHAPTER 10 Application Examples
10.1 WAPA's Kayenta Advanced Series Capacitor (ASC)
10.2 BPA's Slatt Thyristor-Controlled Series Capacitor (TCSC)
10.3 TVA's Sullivan Static Synchronous Compensator (STATCOM)
10.4 AEP's Inez Unified Power Flow Controller (UPFC)
INDEXUnderstanding FACTS : concepts and Technology of Flexible AC Transmission Systems [texte imprimé] / Narain G. Hingorani, Auteur ; Laszlo Gyugyi, Auteur . - New York : IEEE Press /John Wiley & Sons,Inc.,Publication, 1999 . - 428 p. : couv. ill. en coul., ill. ; 25,9 cm.
ISBN : 978-0-7803-3455-7
Langues : Anglais (eng)
Catégories : ELECTROTECHNIQUE Index. décimale : 10-05 Electronique de puissance et industrielle Résumé : Electrical Engineering Understanding FACTS Concepts and Technology of Flexible AC Transmission Systems The Flexible AC Transmission System (FACTS) a new technology based on power electronics offers an opportunity to enhance controllability, stability, and power transfer capability of ac transmission systems. Pioneers in FACTS and leading world experts in power electronics applications, Narain G. Hingorani and Laszlo Gyugyi, have teamed together to bring you the definitive book on FACTS technology. Drs. Hingorani and Gyugyi present a practical approach to FACTS that will enable electrical engineers working in the power industry to understand the principles underlying this advanced system. Understanding FACTS will enhance your expertise in equipment specifications and engineering design, and will offer you an informed view of the future of power electronics in ac transmission systems. This comprehensive reference book provides in–depth discussions on:
Power semiconductor devices
Voltage–sourced and current–sourced converters
Specific FACTS Controllers, including SVC, STATCOM, TCSC, SSSC, UPFC, IPFC plus voltage regulators, phase shifters, and special Controllers with a detailed comparison of their performance attributes
Major FACTS applications in the U.S.
Understanding FACTS is an authoritative resource that is essential reading for electrical engineers who want to stay on the cusp of the power electronics revolution.Note de contenu : Table of Contents:
CHAPTER 1 FACTS Concept and General System Considerations
1.1 Transmission Interconnections
1.2 Flow of Power in an AC System
1.3 What Limits the Loading Capability?
1.4 Power Flow and Dynamic Stability Considerations of a Transmission Interconnection
1.5 Relative Importance of Controllable Parameters
1.6 Basic Types of FACTS Controllers
1.7 Brief Description and Definitions of FACTS Controllers
1.8 Checklist of Possible Benefits from FACTS Technology
1.9 In Perspective: HVDC or FACTS
CHAPTER 2 Power Semiconductor Devices
2.1 Perspective on Power Devices
2.2 Principal High-Power Device Characteristics and Requirements
2.3 Power Device Material
2.4 Diode (Pn Junction)
2.5 Transistor
2.6 Thyristor (without Turn-Off Capability)
2.7 Gate Turn-Off Thyristor (GTO)
2.8 MOS Turn-Off Thyristor (MTO)
2.9 Emitter Turn-Off Thyristor
2.10 Integrated Gate-Commutated Thyristor (GCT and IGCT)
2.11 Insulated Gate Bipolar Transistor (IGBT)
2.12 MOS-Controlled Thyristor (MCT)
CHAPTER 3 Voltage-Sourced Converters
3.1 Basic Concept of Voltage-Sourced Converters
3.2 Single-Phase Full-Wave Bridge Converter Operation
3.3 Single Phase-Leg Operation
3.4 Square-Wave Voltage Harmonics for a Single-Phase Bridge
3.5 Three-Phase Full-Wave Bridge Converter
3.6 Sequence of Valve Conduction Process in Each Phase-Leg
3.7 Transformer Connections for 12-Pulse Operation
3.8 24- and 48-Pulse Operation
3.9 Three-Level Voltage-Sourced Converter
3.10 Pulse-Width Modulation (PWM) Converter
3.11 Generalized Technique of Harmonic Elimination and Voltage Control
3.12 Converter Rating—General Comments
CHAPTER 4 Self- and Line-Commutated Current-Sourced Converters
4.1 Basic Concept of Current-Sourced Converters
4.2 Three-Phase Full-Wave Diode Rectifier
4.3 Thyristor-Based Converter (With Gate Turn-On but Without Gate Turn-Off)
4.4 Current-Sourced Converter with Turn-Off Devices (Current Stiff Converter)
4.5 Current-Sourced Versus Voltage-Sourced Converters
CHAPTER 5 Static Shunt Compensators: SVC and STATCOM
5.1 Objectives of Shunt Compensation
5.2 Methods of Controllable Var Generation
5.3 Static Var Compensators: SVC and STATCOM
5.4 Comparison Between STATCOM and SVC
5.5 Static Var Systems
CHAPTER 6 Static Series Compensators: GCSC, TSSC, TCSC, and SSSC
6.1 Objectives of Series Compensation
6.2 Variable Impedance Type Series Compensators
6.3 Switching Converter Type Series Compensators
6.4 External (System) Control for Series Reactive Compensators
6.5 Summary of Characteristics and Features
CHAPTER 7 Static Voltage and Phase Angle Regulators: TCVR and TCPAR
7.1 Objectives of Voltage and Phase Angle Regulators
7.2 Approaches to Thyristor-Controlled Voltage and Phase Angle Regulators (TCVRs and TCPARs)
7.3 Switching Converter-Based Voltage and Phase Angle Regulators
7.4 Hybrid Phase Angle Regulators
CHAPTER 8 Combined Compensators: Unified Power Flow Controller (UPFC) and Interline Power Flow Controller (IPFC)
8.1 Introduction
8.2 The Unified Power Flow Controller
8.3 The Interline Power Flow Controller (IPFC)
8.4 Generalized and Multifunctional FACTS Controllers
CHAPTER 9 Special Purpose Facts Controllers: NGH-SSR Damping Scheme and Thyristor-Controlled Braking Resistor
9.1 Subsynchronous Resonance
9.2 NGH-SSR Damping Scheme
9.3 Thyristor-Controlled Braking Resistor (TCBR)
CHAPTER 10 Application Examples
10.1 WAPA's Kayenta Advanced Series Capacitor (ASC)
10.2 BPA's Slatt Thyristor-Controlled Series Capacitor (TCSC)
10.3 TVA's Sullivan Static Synchronous Compensator (STATCOM)
10.4 AEP's Inez Unified Power Flow Controller (UPFC)
INDEXExemplaires
Code-barres Cote Support Localisation Section Disponibilité N.Inventaire 1006 10-05-32 Livre Bibliothèque de Génie Electrique- USTO Documentaires Exclu du prêt 1006
Titre : Electromagnetic simulation using the FDTD method Type de document : texte imprimé Auteurs : Dennis Michael Sullivan, Auteur Editeur : New York : IEEE Press /John Wiley & Sons,Inc.,Publication Année de publication : 2000 Collection : IEEE Press series on RF and microwave technology. Importance : 165 p. Présentation : couv. ill. en coul., ill. Format : 26 cm. ISBN/ISSN/EAN : 9780780347471 Langues : Anglais (eng) Catégories : ELECTROTECHNIQUE Index. décimale : 10-06 Electromagnétisme Résumé : You can immediately have the power to perform electromagnetic simulation. If you have a fundamental understanding of electromagnetic theory and the knowledge of at least one high-level computer language, you can begin writing simple electromagnetic simulation programs after reading the first chapter of this book. Electromagnetic Simulation Using the FDTD Method describes the power and flexibility of the finite-difference time-domain method as a direct simulation of Maxwell's equations. The FDTD method takes advantage of today's advanced computing power because its computational requirements increase linearly with the size of the simulation problem. This book begins with a simple one-dimensional simulation and progresses to a three-dimensional simulation. Each chapter contains a concise explanation of an essential concept and instruction on its implementation into computer code. Projects that increase in complexity are included, ranging from simulations in free space to propagation in dispersive media. Peripheral topics that are pertinent to time-domain simulation, such as Z-transforms and the discrete Fourier transform, are also covered. Electromagnetic Simulation Using the FDTD Method is written for anyone who would like to learn electromagnetic simulation using the finite-difference time-domain method. Appropriate as both a textbook and for self-study, this tutorial-style book will provide all the background you will need to begin research or other practical work in electromagnetic simulation. Note de contenu : Contents:
Chapiter1:One-dimensional simulation with the FDTD method --
Chapiter2:More on one-dimensional simulation --
Chapiter3:Two-dimensional simulation --
Chapiter4:Three-dimensional simulation --
Chapiter5:Two applications using FDTD --
Chapiter6:Using FDTD for other types of simulation
Appendix:The Z transform --
Index --
List of C programsElectromagnetic simulation using the FDTD method [texte imprimé] / Dennis Michael Sullivan, Auteur . - New York : IEEE Press /John Wiley & Sons,Inc.,Publication, 2000 . - 165 p. : couv. ill. en coul., ill. ; 26 cm.. - (IEEE Press series on RF and microwave technology.) .
ISSN : 9780780347471
Langues : Anglais (eng)
Catégories : ELECTROTECHNIQUE Index. décimale : 10-06 Electromagnétisme Résumé : You can immediately have the power to perform electromagnetic simulation. If you have a fundamental understanding of electromagnetic theory and the knowledge of at least one high-level computer language, you can begin writing simple electromagnetic simulation programs after reading the first chapter of this book. Electromagnetic Simulation Using the FDTD Method describes the power and flexibility of the finite-difference time-domain method as a direct simulation of Maxwell's equations. The FDTD method takes advantage of today's advanced computing power because its computational requirements increase linearly with the size of the simulation problem. This book begins with a simple one-dimensional simulation and progresses to a three-dimensional simulation. Each chapter contains a concise explanation of an essential concept and instruction on its implementation into computer code. Projects that increase in complexity are included, ranging from simulations in free space to propagation in dispersive media. Peripheral topics that are pertinent to time-domain simulation, such as Z-transforms and the discrete Fourier transform, are also covered. Electromagnetic Simulation Using the FDTD Method is written for anyone who would like to learn electromagnetic simulation using the finite-difference time-domain method. Appropriate as both a textbook and for self-study, this tutorial-style book will provide all the background you will need to begin research or other practical work in electromagnetic simulation. Note de contenu : Contents:
Chapiter1:One-dimensional simulation with the FDTD method --
Chapiter2:More on one-dimensional simulation --
Chapiter3:Two-dimensional simulation --
Chapiter4:Three-dimensional simulation --
Chapiter5:Two applications using FDTD --
Chapiter6:Using FDTD for other types of simulation
Appendix:The Z transform --
Index --
List of C programsExemplaires
Code-barres Cote Support Localisation Section Disponibilité N.Inventaire 1589 10-06-32 Livre Bibliothèque de Génie Electrique- USTO Documentaires Exclu du prêt 1589 2503 10-06-32 Livre Bibliothèque de Génie Electrique- USTO Documentaires Exclu du prêt 2503
Titre : Complex Electromagnetic Problems and Numerical Simulation Approaches Type de document : texte imprimé Auteurs : Levent Sevgi, Auteur Editeur : New York : IEEE Press /John Wiley & Sons,Inc.,Publication Année de publication : 2003 Importance : 381 p. Présentation : couv. ill.,ill. Format : 25,9 cm. ISBN/ISSN/EAN : 978-0-471-43062-9 Langues : Anglais (eng) Catégories : TELECOMMUNICATION Index. décimale : 28-04 Traitement du signal appliqué aux télécommunications Résumé : Today, engineering problems are very complex, requiring powerful computer simulations to power them. For engineers, observable-based parameterization as well as numerically computable forms a with rapid convergent properties if in a series are essential. "Complex Electromagnetic Problems and Numerical Simulation Approaches", along with its companion FTP site, will show you how to take on complex electromagnetic problems and solve them in an accurate and efficient manner. Organized into two distinct parts, this comprehensive resource first introduces you to the concepts, approaches, and numerical simulation techniques that will be used throughout the book and then, in Part II, offers step-by-step guidance as to their practical, real-world applications. Self-contained chapters will enable you to find specific solutions to numerous problems.Filled with in-depth insight and expert advice, "Complex Electromagnetic Problems and Numerical Simulation Approaches": describes ground wave propagation; examines antenna systems; deals with radar cross section (RCS) modeling; explores microstrip network design with FDTD and TLM techniques; discusses electromagnetic compatibility (EMC) and bio-electromagnetics (BEM) modeling; and presents radar simulation.
Whether you're a professional electromagnetic engineer requiring a consolidated overview of the subject or an academic/student who wishes to use powerful simulators as a learning tool, "Complex Electromagnetic Problems and Numerical Simulation Approaches" - with its focus on model development, model justification, and range of validity - is the right book for you.Note de contenu : Table of contents
PART I: NUMERICAL SIMULATION APPROACHES.
PART II: APPLICATIONS.
Chapter 1 Ground Wave Propagation
Chapter 2 Antenna Analysis and Array Processing.
Chapter 3 RCS Predicting and Reduction.
Chapter 4 Microwave Networks Design.
Chapter 5 EMC-BEM Modeling.
Chapter 6 Radar Simulation.
Appendix A: EM Fundamentals.
Appendix B: Tables of Computer Codes.
-Index.Complex Electromagnetic Problems and Numerical Simulation Approaches [texte imprimé] / Levent Sevgi, Auteur . - New York : IEEE Press /John Wiley & Sons,Inc.,Publication, 2003 . - 381 p. : couv. ill.,ill. ; 25,9 cm.
ISBN : 978-0-471-43062-9
Langues : Anglais (eng)
Catégories : TELECOMMUNICATION Index. décimale : 28-04 Traitement du signal appliqué aux télécommunications Résumé : Today, engineering problems are very complex, requiring powerful computer simulations to power them. For engineers, observable-based parameterization as well as numerically computable forms a with rapid convergent properties if in a series are essential. "Complex Electromagnetic Problems and Numerical Simulation Approaches", along with its companion FTP site, will show you how to take on complex electromagnetic problems and solve them in an accurate and efficient manner. Organized into two distinct parts, this comprehensive resource first introduces you to the concepts, approaches, and numerical simulation techniques that will be used throughout the book and then, in Part II, offers step-by-step guidance as to their practical, real-world applications. Self-contained chapters will enable you to find specific solutions to numerous problems.Filled with in-depth insight and expert advice, "Complex Electromagnetic Problems and Numerical Simulation Approaches": describes ground wave propagation; examines antenna systems; deals with radar cross section (RCS) modeling; explores microstrip network design with FDTD and TLM techniques; discusses electromagnetic compatibility (EMC) and bio-electromagnetics (BEM) modeling; and presents radar simulation.
Whether you're a professional electromagnetic engineer requiring a consolidated overview of the subject or an academic/student who wishes to use powerful simulators as a learning tool, "Complex Electromagnetic Problems and Numerical Simulation Approaches" - with its focus on model development, model justification, and range of validity - is the right book for you.Note de contenu : Table of contents
PART I: NUMERICAL SIMULATION APPROACHES.
PART II: APPLICATIONS.
Chapter 1 Ground Wave Propagation
Chapter 2 Antenna Analysis and Array Processing.
Chapter 3 RCS Predicting and Reduction.
Chapter 4 Microwave Networks Design.
Chapter 5 EMC-BEM Modeling.
Chapter 6 Radar Simulation.
Appendix A: EM Fundamentals.
Appendix B: Tables of Computer Codes.
-Index.Exemplaires
Code-barres Cote Support Localisation Section Disponibilité N.Inventaire 622 28-04-05 Livre Bibliothèque de Génie Electrique- USTO Documentaires Exclu du prêt 622
