Advances in Power System Modelling, Control and Stability Analysis
Power systems are becoming increasingly complex as well as flexible, able to integrate distributed renewable generation, EV, and additional loads. This expanded and updated second edition covers the technologies needed to operate modern power grids.

Initial chapters cover power system modelling, telegrapher equations, power flow analysis, discrete Fourier transformation and stochastic differential equations. Ensuing chapters deal with power system operation and control, power flow, real-time control and state estimation techniques for distribution systems as well as shipboard systems. The final chapters describe stability analysis of power systems and cover voltage stability, transient stability, time delays, and limit cycles. New content for the second edition includes four new chapters on recent modelling, control and stability analysis of power electronic converters and electric vehicles.

This new edition is an essential guide to technologies for operating modern flexible power systems for PhD students, early-career researchers and practitioners in the field.

1123977515
Advances in Power System Modelling, Control and Stability Analysis
Power systems are becoming increasingly complex as well as flexible, able to integrate distributed renewable generation, EV, and additional loads. This expanded and updated second edition covers the technologies needed to operate modern power grids.

Initial chapters cover power system modelling, telegrapher equations, power flow analysis, discrete Fourier transformation and stochastic differential equations. Ensuing chapters deal with power system operation and control, power flow, real-time control and state estimation techniques for distribution systems as well as shipboard systems. The final chapters describe stability analysis of power systems and cover voltage stability, transient stability, time delays, and limit cycles. New content for the second edition includes four new chapters on recent modelling, control and stability analysis of power electronic converters and electric vehicles.

This new edition is an essential guide to technologies for operating modern flexible power systems for PhD students, early-career researchers and practitioners in the field.

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Advances in Power System Modelling, Control and Stability Analysis

Advances in Power System Modelling, Control and Stability Analysis

by Federico Milano (Editor)
Advances in Power System Modelling, Control and Stability Analysis

Advances in Power System Modelling, Control and Stability Analysis

by Federico Milano (Editor)

Overview

Power systems are becoming increasingly complex as well as flexible, able to integrate distributed renewable generation, EV, and additional loads. This expanded and updated second edition covers the technologies needed to operate modern power grids.

Initial chapters cover power system modelling, telegrapher equations, power flow analysis, discrete Fourier transformation and stochastic differential equations. Ensuing chapters deal with power system operation and control, power flow, real-time control and state estimation techniques for distribution systems as well as shipboard systems. The final chapters describe stability analysis of power systems and cover voltage stability, transient stability, time delays, and limit cycles. New content for the second edition includes four new chapters on recent modelling, control and stability analysis of power electronic converters and electric vehicles.

This new edition is an essential guide to technologies for operating modern flexible power systems for PhD students, early-career researchers and practitioners in the field.

Product Details

ISBN-13: 9781839535758
Publisher: The Institution of Engineering and Technology
Publication date: 11/04/2022
Series: Energy Engineering
Edition description: 2nd ed.
Pages: 764
Product dimensions: 6.14(w) x 9.21(h) x (d)

About the Author

Federico Milano is a Professor in Power Systems Control and Protections at the UniversityCollege Dublin School of Electrical and Electronic Engineering. His research interests include power systems modelling, control and stability analysis, distributed and renewable generation, bifurcation theory, and parallel computing. He is an IEEE Fellow and an editor of several journals including IET Generation, Transmission & Distribution and IEEE Transactions on Power Systems. He also chaired the IEEE PES Task Force on Free & Open Source Software.

Table of Contents

  • Part I: Modelling
    • Chapter 1: Telegrapher's equations for field-to-transmission line interaction
    • Chapter 2: Reliable solutions of uncertain optimal power flow problems by affine arithmetic
    • Chapter 3: DFT-based synchrophasor estimation processes for Phasor Measurement Units applications: algorithms definition and performance analysis
    • Chapter 4: Modeling power systems with stochastic processes
    • Chapter 5: Detailed modeling of inverter-based resources
    • Chapter 6: Isomorphism-based simulation of modular multilevel converters
  • Part II: Control
    • Chapter 7: Optimization methods for preventive/corrective control in transmission systems
    • Chapter 8: Static and recursive PMU-based state estimation processes for transmission and distribution power grids
    • Chapter 9: Real-time applications for electric power generation and voltage control
    • Chapter 10: Optimal control processes in active distribution networks
    • Chapter 11: Control of converter interfaced generation
    • Chapter 12: Combined voltage - frequency control with power electronics-based devices
    • Chapter 13: Smart transformer control of the electrical grid
    • Chapter 14: On the interactions between plug-in electric vehicles and the power grid
  • Part III: Stability Analysis
    • Chapter 15: Time-domain simulation for transient stability analysis
    • Chapter 16: Voltage security in modern power systems
    • Chapter 17: Small-signal stability and time-domain analysis of delayed power systems
    • Chapter 18: Shooting-based stability analysis of power system oscillations
    • Chapter 19: Stability assessment in advanced DC microgrids
    • Chapter 20: Scanning methods for stability analysis of inverter-based resources
  • Part IV: Appendices
    • Appendix A: Stochastic process fitting procedure
    • Appendix B: Modeling correlated stochastic processes
    • Appendix C: Data of lines, loads and distributed energy resources
    • Appendix D: Proofs and tools for DDAEs
    • Appendix E: Numerical aspects of the probe-insertion technique
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