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Transient analysis of power systems : solution techniques, tools, and applications /
"The simulation of electromagnetic transients is a mature field that plays an important role in the design of modern power systems. Since the first steps in this field to date, a significant effort has been dedicated to the development of new techniques and more powerful software tools. Sophist...
| Clasificación: | Libro Electrónico |
|---|---|
| Autor principal: | |
| Formato: | Electrónico eBook |
| Idioma: | Inglés |
| Publicado: |
Chichester, West Sussex, United Kingdom :
IEEE Press/ John Wiley & Sons, Inc.,
2014.
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| Temas: | |
| Acceso en línea: | Texto completo |
Tabla de Contenidos:
- Transient Analysis of Power Systems; Contents; Preface; About the Editor; List of Contributors; 1 Introduction to Electromagnetic Transient Analysis of Power Systems; 1.1 Overview; 1.2 Scope of the Book; References; 2 Solution Techniques for Electromagnetic Transients in Power Systems; 2.1 Introduction; 2.2 Application Field for the Computation of Electromagnetic Transients; 2.3 The Main Modules; 2.4 Graphical User Interface; 2.5 Formulation of Network Equations for Steady-State and Time-Domain Solutions; 2.5.1 Nodal Analysis and Modified-Augmented-Nodal-Analysis; 2.5.2 State-Space Analysis.
- 2.5.3 Hybrid Analysis2.5.4 State-Space Groups and MANA; 2.5.5 Integration Time-Step; 2.6 Control Systems; 2.7 Multiphase Load-Flow Solution and Initialization; 2.7.1 Load-Flow Constraints; 2.7.2 Initialization of Load-Flow Equations; 2.7.3 Initialization from Steady-State Solution; 2.8 Implementation; 2.9 Conclusions; References; 3 Frequency Domain Aspects of Electromagnetic Transient Analysis of Power Systems; 3.1 Introduction; 3.2 Frequency Domain Basics; 3.2.1 Phasors and FD Representation of Signals; 3.2.2 Fourier Series; 3.2.3 Fourier Transform; 3.3 Discrete-Time Frequency Analysis.
- 3.3.1 Aliasing Effect3.3.2 Sampling Theorem; 3.3.3 Conservation of Information and the DFT; 3.3.4 Fast Fourier Transform; 3.4 Frequency-Domain Transient Analysis; 3.4.1 Fourier Transforms and Transients; 3.4.2 Fourier and Laplace Transforms; 3.4.3 The Numerical Laplace Transform; 3.4.4 Application Examples with the NLT; 3.4.5 Brief History of NLT Development; 3.5 Multirate Transient Analysis; 3.6 Conclusions; Acknowledgement; References; 4 Real-Time Simulation Technologies in Engineering; 4.1 Introduction; 4.2 Model-Based Design and Real-Time Simulation.
- 4.3 General Considerations about Real-Time Simulation4.3.1 The Constraint of Real-Time; 4.3.2 Stiffness Issues; 4.3.3 Simulator Bandwidth Considerations; 4.3.4 Simulation Bandwidth vs. Applications; 4.3.5 Achieving Very Low Latency for HIL Application; 4.3.6 Effective Parallel Processing for Fast EMT Simulation; 4.3.7 FPGA-Based Multirate Simulators; 4.3.8 Advanced Parallel Solvers without Artificial Delays or Stublines: Application to Active Distribution Networks; 4.3.9 The Need for Iterations in Real-Time; 4.4 Phasor-Mode Real-Time Simulation; 4.5 Modern Real-Time Simulator Requirements.
- 4.5.1 Simulator I/O Requirements4.6 Rapid Control Prototyping and Hardware-in-the-Loop Testing; 4.7 Power Grid Real-Time Simulation Applications; 4.7.1 Statistical Protection System Study; 4.7.2 Monte Carlo Tests for Power Grid Switching Surge System Studies; 4.7.3 Modular Multilevel Converter in HVDC Applications; 4.7.4 High-End Super-Large Power Grid Simulations; 4.8 Motor Drive and FPGA-Based Real-Time Simulation Applications; 4.8.1 Industrial Motor Drive Design and Testing Using CPU Models; 4.8.2 FPGA Modelling of SRM and PMSM Motor Drives.