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Power System Monitoring and Control

Book Description

Power System Monitoring and Control presents a comprehensive overview of the basic principles and key technologies for the monitoring, protection, and control of contemporary wide-area power systems.

  • Provides an updated and comprehensive reference for researcher and engineers working on wide-area power system monitoring and control (PSMC)

  • Links fundamental concepts of PSMC, advanced metering and control theory/techniques, and practical engineering considerations

  • Covers PSMC problem understanding, design, practical aspects, and timely topics such as smart/microgrid control and coordinated voltage regulation and angle oscillation damping

  • Incorporates authors' experiences teaching and researching in various international locales including Japan, Thailand, Singapore, Malaysia, Iran, and Australia

  • Table of Contents

    1. Cover
    2. Title Page
    3. Copyright
    4. Dedication
    5. Preface
    6. Acknowledgments
    7. Chapter 1: An Introduction on Power System Monitoring
      1. 1.1 Synchronized Phasor Measurement
      2. 1.2 Power System Monitoring and Control with Wide-Area Measurements
      3. 1.3 ICT Architecture Used in Wide-Area Power System Monitoring and Control
      4. 1.4 Summary
      5. References
    8. Chapter 2: Oscillation Dynamics Analysis Based on Phasor Measurements
      1. 2.1 Oscillation Characteristics in Power Systems
      2. 2.2 An Overview of Oscillation Monitoring Using Phasor Measurements
      3. 2.3 Wams-Based Interarea Mode Identification
      4. 2.4 Low-Frequency Oscillation Dynamics
      5. 2.5 Summary
      6. References
    9. Chapter 3: Small-Signal Stability Assessment
      1. 3.1 Power System Small-Signal Stability
      2. 3.2 Oscillation Model Identification Using Phasor Measurements
      3. 3.3 Small-Signal Stability Assessment of Wide-Area Power System
      4. 3.4 Summary
      5. References
    10. Chapter 4: Graphical Tools for Stability and Security Assessment
      1. 4.1 Importance of Graphical Tools in WAMS
      2. 4.2 Angle–Voltage Deviation Graph
      3. 4.3 Simulation Results
      4. 4.4 Voltage–Frequency Deviation Graph
      5. 4.5 Frequency–Angle Deviation Graph [8]
      6. 4.6 Electromechanical Wave Propagation Graph
      7. 4.7 Summary
      8. References
    11. Chapter 5: Power System Control: Fundamentals and New Perspectives
      1. 5.1 Power System Stability and Control [5]
      2. 5.2 Angle and Voltage Control
      3. 5.3 Frequency Control [10,11]
      4. 5.4 Supervisory Control and Data Acquisition
      5. 5.5 Challenges, Opportunities, and New Perspectives
      6. 5.6 Summary
      7. References
    12. Chapter 6: Wide-Area Measurement-Based Power System Control Design
      1. 6.1 Measurement-Based Controller Design
      2. 6.2 Controller Tuning Using a Vibration Model
      3. 6.3 Wide-Area Measurement-Based Controller Design
      4. 6.4 Summary
      5. References
    13. Chapter 7: Coordinated Dynamic Stability and Voltage Regulation
      1. 7.1 Need for AVR–PSS Coordination
      2. 7.2 A Survey on Recent Achievements
      3. 7.3 A Robust Simultaneous AVR–PSS Synthesis Approach
      4. 7.4 A Wide-Area Measurement-Based Coordination Approach
      5. 7.5 Intelligent AVR and PSS Coordination Design
      6. 7.6 Summary
      7. References
    14. Chapter 8: Wide-Area Measurement-Based Emergency Control
      1. 8.1 Conventional Load Shedding and New Challenges
      2. 8.2 Need for Monitoring Both Voltage and Frequency
      3. 8.3 Simultaneous Voltage and Frequency-Based LS
      4. 8.4 Wave Propagation-Based Emergency Control
      5. 8.5 Summary
      6. References
    15. Chapter 9: Microgrid Control: Concepts and Classification
      1. 9.1 Microgrids
      2. 9.2 Microgrid Control [1]
      3. 9.3 Local Controls
      4. 9.4 Secondary Controls
      5. 9.5 Global Controls
      6. 9.6 Central/Emergency Controls
      7. 9.7 Summary
      8. References
    16. Chapter 10: Microgrid Control: Synthesis Examples
      1. 10.1 Local Control Synthesis
      2. 10.2 Secondary Control Synthesis
      3. 10.3 Global Control Synthesis
      4. 10.4 Emergency Control Synthesis
      5. 10.5 Summary
      6. References
    17. Appendix A: New York/New England 16-Machine 68-Bus System Case Study
    18. Appendix B: Nine-Bus Power System Case Study
    19. Appendix C: Four-Order Dynamical Power System Model and Parameters of the Four-Machine Infinite-Bus System
    20. Index
    21. End User License Agreement