Power System Dynamics and Control
Power System Dynamics and Control. Instructor: Prof. A. M. Kulkarni, Department of Electrical Engineering, IIT Bombay. This course introduces a student to power stability problems and the basic concepts of modeling and analysis of dynamical systems. Modeling of power system components - generators, transmission lines, excitation and prime mover controllers - is covered in detail. Stability of single machine and multi-machine systems is analyzed using digital simulation and small-signal analysis techniques. The impact of stability problems on power system planning, and operation is also brought out.
(from nptel.ac.in )
Lecture 10 - Numerical Integration (cont.)
VIDEO
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Lecture 01 - Introduction
Lecture 02 - Introduction: Voltage and Frequency Stability, Control Hierarchy
Lecture 03 - Analysis of Dynamical Systems
Lecture 04 - Analysis of Dynamical Systems (cont.)
Lecture 05 - Analysis of Linear Time Invariant Dynamical Systems
Lecture 06 - Analysis of Linear Time Invariant Dynamical Systems (cont.)
Lecture 07 - Stiff Systems, Multi Time Scaling Modeling
Lecture 08 - Numerical Integration
Lecture 09 - Numerical Integration (cont.)
Lecture 10 - Numerical Integration (cont.)
Lecture 11 - Modeling of Synchronous Machines
Lecture 12 - Modeling of Synchronous Machines (cont.)
Lecture 13 - Modeling of Synchronous Machines (cont.)
Lecture 14 - Modeling of Synchronous Machines: dq0 Transformation
Lecture 15 - Modeling of Synchronous Machines: Standard Parameters
Lecture 16 - Modeling of Synchronous Machines: Standard Parameters (cont.)
Lecture 17 - Synchronous Generator Models using Standard Parameters
Lecture 18 - Synchronous Generator Models using Standard Parameters: Per Unit Representation
Lecture 19 - Open Circuit Response of a Synchronous Generator
Lecture 20 - Synchronous Machine Modelling: Short Circuit Analysis
Lecture 21 - Synchronous Machine Modelling: Short Circuit Analysis; Synchronization of a Synchronous Machine
Lecture 22 - Synchronization of a Synchronous Machine (cont.)
Lecture 23 - Simplified Synchronous Machine Models
Lecture 24 - Excitation Systems
Lecture 25 - Excitation System Modeling
Lecture 26 - Excitation System Modeling: Automatic Voltage Regulator
Lecture 27 - Excitation System Modeling: Automatic Voltage Regulator (cont.)
Lecture 28 - Excitation System Modeling: Automatic Voltage Regulator: Simulation
Lecture 29 - Excitation System Modeling: Automatic Voltage Regulator: Simulation (cont.)
Lecture 30 - Excitation System Modeling: Automatic Voltage Regulator: Linearized Analysis
Lecture 31 - Load Modeling
Lecture 32 - Induction Machines, Transmission Lines
Lecture 33 - Transmission Lines, Prime Mover System
Lecture 34 - Transmission Lines (cont.), Prime Mover Systems
Lecture 35 - Prime Mover Systems, Stability in Integrated Power System
Lecture 36 - Stability in Integrated Power System: Two Machine Example
Lecture 37 - Stability in Integrated Power System: Two Machine System (cont.)
Lecture 38 - Stability in Integrated Power System: Large Systems
Lecture 39 - Frequency/Angular Stability Programs, Stability Phenomena: Voltage Stability Example
Lecture 40 - Voltage Stability Example (cont.), Fast Transients: Tools and Phenomena
Lecture 41 - Torsional Transients: Phenomena of Sub-Synchronous Resonance
Lecture 42 - Sub-Synchronous Resonance, Stability Improvement
Lecture 43 - Stability Improvement
Lecture 44 - Stability Improvement, Power System Stabilizers
Lecture 45 - Stability Improvement (Large Disturbance Stability)