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Bevrani, Hassan [Verfasser:in] ; Watanabe, Masayuki [Sonstige Person, Familie und Körperschaft]; Mitani, Yasunori [Sonstige Person, Familie und Körperschaft]

Power system monitoring and control

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  • Medientyp: E-Book
  • Titel: Power system monitoring and control
  • Beteiligte: Bevrani, Hassan [Verfasser:in]; Watanabe, Masayuki [Sonstige Person, Familie und Körperschaft]; Mitani, Yasunori [Sonstige Person, Familie und Körperschaft]
  • Erschienen: Hoboken, New Jersey: Wiley, 2014
  • Umfang: 1 Online-Ressource (1 online resource)
  • Sprache: Englisch
  • DOI: 10.1002/9781118852422
  • ISBN: 1118852478; 1118852648; 1118852427; 1306821363; 9781118852644; 9781118852422; 9781118852477; 9781306821360
  • Identifikator:
  • Schlagwörter: Electric power systems Control ; TECHNOLOGY & ENGINEERING ; Power Resources ; Alternative & Renewable ; Electric power systems ; Control ; Réseaux électriques (Énergie) - Régulation ; Electronic books
  • Entstehung:
  • Anmerkungen: Includes bibliographical references and index
  • Beschreibung: "The book is a reference for researchers and engineers working on power system control and operation"--

    "Providing full coverage of the basic principles on the subject, Wide Area Power System Monitoring and Control highlights key technologies for monitoring, protection, and control. The strong author team explores a host of cutting-edge topics, including renewable energy sources, smart grids, wide area stabilizing, as well as coordinated voltage regulation and angle oscillation damping. Complemented by end-of-chapter problems and solutions, as well as case studies, this comprehensive handbook provides engineers/operators and graduate students with an in-depth overview of WPSMC understanding, analysis, synthesis, and implementation"--

    Preface vii -- About the Author ix -- About the Contributor ix -- INTRODUCTION 1 -- Chapter 1: Beginning Your CPA Review Program 3 -- Chapter 2: Examination Grading 17 -- Chapter 3: The Solutions Approach 19 -- Chapter 4: Taking The Examination 27 -- Chapter 5: Exam Content Overview 31 -- FINANCIAL ACCOUNTING AND REPORTING 39 -- Module 9: Basic Theory and Financial Reporting 41 -- Module 10: Inventory 217 -- Module 11: Fixed Assets 267 -- Module 12: Monetary Current Assets and Current Liabilities 329 -- Module 13: Present Value 395 -- Module 14: Deferred Taxes 537 -- Module 15: Stockholders' Equity 577 -- Module 16: Investments 639 -- Module 17: Statement of Cash Flows 687 -- Module 18: Business Combinations and Consolidations 725 -- Module 19: Derivative Instruments and Hedging Activities 785 -- Module 20: Miscellaneous 825 -- Module 21: Governmental (State and Local) Accounting 897 -- Module 22: Not-for-Profit Accounting 983 -- APPENDICES 1017 -- Appendix A: Outlines of Accounting Pronouncements 1019 -- Appendix B: Financial Accounting and Reporting Sample Examination 1137 -- Appendix C: Sample Financial Accounting and Reporting Testlet Released by AICPA 1171 -- Appendix D: 2014 Released AICPA Questions for Financial Accounting and Reporting 1179 -- INDEX 1201.

    Machine generated contents note:1.1.Synchronized Phasor Measurement --1.2.Power System Monitoring and Control with Wide-Area Measurements --1.3.ICT Architecture Used in Wide-Area Power System Monitoring and Control --1.4.Summary --References --2.1.Oscillation Characteristics in Power Systems --2.1.1.Eigenvalue Analysis and Participation Factor --2.1.2.Oscillation Characteristics in an Interconnected Power System --2.2.Overview of Oscillation Monitoring Using Phasor Measurements --2.2.1.Monitoring of the Japan Power Network --2.2.2.Monitoring of the Southeast Asia Power Network --2.3.WAMS-Based Interarea Mode Identification --2.4.Low-Frequency Oscillation Dynamics --2.4.1.Electromechanical Modes Characteristics --2.4.2.Oscillation Characteristics Analyses in Southeast Asia Power Network --2.5.Summary --References --3.1.Power System Small-Signal Stability --3.2.Oscillation Model Identification Using Phasor Measurements --3.2.1.Oscillation Model of the Electromechanical Mode --3.2.2.Dominant Mode Identification with Signal Filtering --3.3.Small-Signal Stability Assessment of Wide-Area Power System --3:3:1.Simulation Study --3.3.2.Stability Assessment Based on Phasor Measurements --3.3.3.Stability Assessment Based on Frequency Monitoring --3.4.Summary --References --4.1.Importance of Graphical Tools in WAMS --4.2.Angle[--]Voltage Deviation Graph --4.3.Simulation Results --4.3.1.Disturbance in Generation Side --4.3.2.Disturbance in Demand Side --4.4.Voltage[--]Frequency Deviation Graph --4.4.1.ΔV-ΔF Graph for Contingency Assessment --4.4.2.ΔV-ΔF Graph for Load Shedding Synthesis --4.5.Frequency[--]Angle Deviation Graph --4.6.Electromechanical Wave Propagation Graph --4.6.1.Wave Propagation --4.6.2.Angle Wave and System Configuration --4.7.Summary --References --5.1.Power System Stability and Control --5.2.Angle and Voltage Control --5.3.Frequency Control --5.3.1.Frequency Control Dynamic --5.3.2.Operating States and Power Reserves --5.4.Supervisory Control and Data Acquisition --5.5.Challenges, Opportunities, and New Perspectives --5.5.1.Application of Advanced Control Methods and Technologies --5.5.2.Standards Updating --5.5.3.Impacts of Renewable Energy Options --5.5.4.RESs Contribution to Regulation Services --5.6.Summary --References --6.1.Measurement-Based Controller Design --6.2.Controller Tuning Using a Vibration Model --6.2.1.Vibration Model Including the Effect of Damping Controllers --6.2.2.Tuning Mechanism --6.2.3.Simulation Results --6.3.Wide-Area Measurement-Based Controller Design --6.3.1.Wide-Area Power System Identification --6.3.2.Design Procedure --6.3.3.Simulation Results --6.4.Summary --References --7.1.Need for AVR[--]PSS Coordination --7.2.Survey on Recent Achievements --7.3.Robust Simultaneous AVR[--]PSS Synthesis Approach --7.3.1.Control Framework --7.3.2.Developed Algorithm --7.3.3.Real-Time Implementation --7.3.4.Experiment Results --7.4.Wide-Area Measurement-Based Coordination Approach --7.4.1.High Penetration of Wind Power --7.4.2.Developed Algorithm --7.4.3.Application Example --7.4.4.Simulation Results --7.5.Intelligent AVR and PSS Coordination Design --7.5.1.Fuzzy Logic-Based Coordination System --7.5.2.Simulation Results --7.6.Summary --References --8.1.Conventional Load Shedding and New Challenges --8.1.1.Load Shedding: Concept and Review --8.1.2.Some Key Issues --8.2.Need for Monitoring Both Voltage and Frequency --8.3.Simultaneous Voltage and Frequency: Based LS --8.3.1.Proposed LS Scheme --8.3.2.Implementation --8.3.3.Case Studies and Simulation Results --8.3.4.Approach for Optimal UFVLS --8.3.5.Discussion --8.4.Wave Propagation-Based Emergency Control --8.4.1.Proposed Control Scheme --8.4.2.Simulation Results --8.5.Summary --References --9.1.Microgrids --9.2.Microgrid Control --9.3.Local Controls --9.4.Secondary Controls --9.5.Global Controls --9.6.Central/Emergency Controls --9.7.Summary --References --10.1.Local Control Synthesis --10.1.1.Robust Voltage Control Design --10.1.2.Intelligent Droop-Based Voltage and Frequency Control --10.2.Secondary Control Synthesis --10.2.1.Intelligent Frequency Control --10.2.2.ANN-Based Self-Tuning Frequency Control --10.3.Global Control Synthesis --10.3.1.Adaptive Energy Consumption Scheduling --10.3.2.Power Dispatching in Interconnected MGs --10.4.Emergency Control Synthesis --10.4.1.Developed LS Algorithm --10.4.2.Case Study and Simulation --10.5.Summary --References.