Power system dynamics and stability : with synchrophasor measurement and power system toolbox

Content: Power System Dynamics and Stability
Contents
Preface
About the Companion Website
1 Introduction
1.1 Background
1.2 Physical Structures
1.3 Time-Scale Structures
1.4 Political Structures
1.5 The Phenomena of Interest
1.6 New Chapters Added to this Edition
2 Electromagnetic Transients
2.1 The Fastest Transients
2.2 Transmission Line Models
2.3 Solution Methods
2.4 Problems
3 Synchronous Machine Modeling
3.1 Conventions and Notation
3.2 Three-Damper-Winding Model
3.3 Transformations and Scaling
3.4 The Linear Magnetic Circuit
3.5 The Nonlinear Magnetic Circuit 3.6 Single-Machine Steady State3.7 Operational Impedances and Test Data
3.8 Problems
4 Synchronous Machine Control Models
4.1 Voltage and Speed Control Overview
4.2 Exciter Models
4.3 Voltage Regulator Models
4.4 Turbine Models
4.4.1 Hydroturbines
4.4.2 Steam Turbines
4.5 Speed Governor Models
4.6 Problems
5 Single-Machine Dynamic Models
5.1 Terminal Constraints
5.2 The Multi-Time-Scale Model
5.3 Elimination of Stator/Network Transients
5.4 The Two-Axis Model
5.5 The One-Axis (Flux-Decay) Model
5.6 The Classical Model
5.7 Damping Torques 5.8 Single-Machine Infinite-Bus System5.9 Synchronous Machine Saturation
5.10 Problems
6 Multimachine Dynamic Models
6.1 The Synchronously Rotating Reference Frame
6.2 Network and R-L Load Constraints
6.3 Elimination of Stator/Network Transients
6.3.1 Generalization of Network and Load Dynamic Models
6.3.2 The Special Case of "Impedance Loads"
6.4 Multimachine Two-Axis Model
6.4.1 The Special Case of "Impedance Loads"
6.5 Multimachine Flux-Decay Model
6.5.1 The Special Case of "Impedance Loads"
6.6 Multimachine Classical Model
6.6.1 The Special Case of "Impedance Loads" 6.7 Multimachine Damping Torques6.8 Multimachine Models with Saturation
6.8.1 The Multimachine Two-Axis Model with Synchronous Machine Saturation
6.8.2 The Multimachine Flux-Decay Model with Synchronous Machine Saturation
6.9 Frequency During Transients
6.10 Angle References and an Infinite Bus
6.11 Automatic Generation Control (AGC)
7 Multimachine Simulation
7.1 Differential-Algebraic Model
7.1.1 Generator Buses
7.1.2 Load Buses
7.2 Stator Algebraic Equations
7.2.1 Polar Form
7.2.2 Rectangular Form
7.2.3 Alternate Form of Stator Algebraic Equations
7.3 Network Equations 7.3.1 Power-Balance Form7.3.2 Real Power Equations
7.3.3 Reactive Power Equations
7.3.4 Current-Balance Form
7.4 Industry Model
7.5 Simplification of the Two-Axis Model
7.5.1 Simplification #1 (Neglecting Transient Saliency in the Synchronous Machine)
7.5.2 Simplification #2 (Constant Impedance Load in the Transmission System)
7.6 Initial Conditions (Full Model)
7.6.1 Load-Flow Formulation
7.6.2 Standard Load Flow
7.6.3 Initial Conditions for Dynamic Analysis
7.6.4 Angle Reference, Infinite Bus, and COI Reference
7.7 Numerical Solution: Power-Balance Form
7.7.1 SI Method