TY  - BOOK
AU  - Momoh,James A.
AU  - El-Hawary,M.E.
TI  - Electric systems, dynamics, and stability with artificial intelligence applications
T2  - Power engineering
AV  - TK1010 .M65 2000
PY  - 2000///
CY  - New York
PB  - M. Dekker
KW  - Electric power system stability
KW  - Mathematical models
KW  - Artificial intelligence
KW  - Electric power systems
KW  - Automatic control
KW  - Data processing
N1  - Includes bibliographical references (pages 332-349) and index; Contents;  	Series Introduction; / H. Lee Willis;  	Preface; 1	Introduction; 2	Static Electric Network Models;  	2.1	Complex Power Concepts;  	2.2	Three-Phase Systems;  	2.3	Synchronous Machine Modeling;  	2.4	Reactive Capability Limits;  	2.5	Static Load Models; 3	Dynamic Electric Network Models;  	3.1	Excitation System Model;  	3.2	Prime Mover and Governing System Models;  	3.3	Modeling of Loads; 4	Philosophy of Security Assessment;  	4.1	The Swing Equation;  	4.2	Some Alternative Forms;  	4.3	Transient and Subtransient Reactances;  	4.4	Synchronous Machine Model in Stability Analysis;  	4.5	Subtransient Equations;  	4.6	Machine Models;  	4.7	Groups of Machines and the Infinite Bus;  	4.8	Stability Assessment;  	4.9	Concepts in Transient Stability;  	4.10	A Method for Stability Assessment;  	4.11	Mathematical Models and Solution Methods in Transient Stability Assessment for General Networks;  	4.12	Integration Techniques;  	4.13	The Transient Stability Algorithm; 5	Assessing Angle Stability via Transient Energy Function;  	5.1	Stability Concepts;  	5.2	System Model Description;  	5.3	Stability of a Single-Machine System;  	5.4	Stability Assessment for n-Generator System by the TEF Method;  	5.5	Application to a Practical Power System;  	5.6	Boundary of the Region of Stability; 6	Voltage Stability Assessment;  	6.1	Working Definition of Voltage Collapse Study Terms;  	6.2	Typical Scenario of Voltage Collapse;  	6.3	Time-Frame Voltage Stability;  	6.4	Modeling for Voltage Stability Studies;  	6.5	Voltage Collapse Prediction Methods;  	6.6	Classification of Voltage Stability Problems;  	6.7	Voltage Stability Assessment Techniques;  	6.8	Analysis Techniques for Steady-State Voltage Stability Studies;  	6.9	Parameterization;  	6.10	The Technique of Modal Analysis;  	6.11	Analysis Techniques for Dynamic Voltage Stability Studies; 7	Technology of Intelligent Systems;  	7.1	Fuzzy Logic and Decision Trees;  	7.2	Artificial Neural Networks;  	7.3	Robust Artificial Neural Network;  	7.4	Expert Systems;  	7.5	Fuzzy Sets and Systems;  	7.6	Expert Reasoning and Approximate Reasoning; 8	Application of Artificial Intelligence to Angle Stability Studies;  	8.1	ANN Application in Transient Stability Assessment;  	8.2	A Knowledge-Based System for Direct Stability Analysis; 9	Application of Artificial Intelligence to Voltage Stability Assessment and Enhancement to Electrical Power Systems;  	9.1	ANN-Based Voltage Stability Assessment;  	9.2	ANN-Based Voltage Stability Enhancement;  	9.3	A Knowledge-Based Support System for Voltage Collapse Detection and Prevention;  	9.4	Implementation for KBVCDP;  	9.5	Utility Environment Application; 10	Epilogue and Conclusions;  	Glossary;  	Appendix: Chapter Problems;  	Bibliography;  	Index
ER  -