Open AccessANN Based SVC FACTS Controller to Enhance Voltage Stability of Multi-Machine Power System
Author(s) -
Suman Machavarapu,
M. Venkateswara Rao,
P.V.Ramana Rao
Publication year - 2019
Publication title -
international journal of innovative technology and exploring engineering
Language(s) - English
Resource type - Journals
ISSN - 2278-3075
DOI - 10.35940/ijitee.i8401.0881019
Subject(s) - susceptance , control theory (sociology) , static var compensator , electric power system , ac power , voltage , controller (irrigation) , matlab , engineering , computer science , power (physics) , electrical engineering , control (management) , agronomy , physics , quantum mechanics , artificial intelligence , biology , operating system
Voltage stability is the most vital phenomena in power systems which may be disturbed by the mismatch between the reactive power supply and demand. The occurrence of internal faults in the equipment and short circuit faults also there may be voltage collapse at the buses. Voltage stability can be improved using Static VAR Compensator (SVC) which is a shunt device. It can generate or absorb reactive power in a controlled manner such that it can enhance voltage stability of the system. LIndex method is used to determine voltage sensitivity at each bus and the bus having highest L- index value can be considered as a weak bus which is the optimal location of FACTS controller. The investigation is made to observe how susceptance in susceptance model and firing angle in firing angle model of the SVC is predicted to enhance the voltage at each bus by the artificial neural network under chaotic load. Standard IEEE 5 bus and 30 bus systems are considered as test systems and simulations are performed in MATLAB software.