Design, Modelling and Simulation of Fuzzy Controlled SVC for 750 km (λ/8) Transmission Line
American Journal of Electrical Power and Energy Systems
Volume 3, Issue 1, January 2014, Pages: 1-6
Received: Dec. 4, 2013;
Published: Jan. 10, 2014
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Murali. Matcha, Department of Electrical Engineering, N.I.T Warangal, A.P, INDIA-506004
Sharath Kumar. Papani, Department of Electrical Engineering, N.I.T Warangal, A.P, INDIA-506004
Vijetha. Killamsetti, Department of EEE, GMR Institute of Technology, Srikakulam, A.P, INDIA
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Flexible AC transmission system (FACTS) is a technology, which is based on power electronic devices, used to enhance the existing transmission capabilities in order to make the transmission system flexible and independent operation. The FACTS technology is a promising technology to achieve complete deregulation of Power System i.e. Generation, Transmission and Distribution as complete individual units. The loading capability of transmission system can also be enhanced nearer to the thermal limits without affecting the stability. Complete close-loop smooth control of reactive power can be achieved using shunt connected FACTS devices. Static VAR Compensator (SVC) is one of the shunt connected FACTS device, which can be utilized for the purpose of reactive power compensation. Intelligent FACTS devices make them adaptable and hence it is emerging in the present state of art. This paper attempts to design and simulate the Fuzzy logic control of firing angle for SVC in order to achieve better, smooth and adaptive control of reactive power. The design, modeling and simulations are carried out for λ /8 Transmission line and the compensation is placed at the receiving end (load end).
Fuzzy Logic, FACTS, SVC
To cite this article
Sharath Kumar. Papani,
Design, Modelling and Simulation of Fuzzy Controlled SVC for 750 km (λ/8) Transmission Line, American Journal of Electrical Power and Energy Systems.
Vol. 3, No. 1,
2014, pp. 1-6.
Narain. G. Hingorani, "Understanding FACTS, Concepts and Technology Of flexible AC Transmission Systems", by IEEE Press USA.
Bart Kosko, "Neural Networks and Fuzzy Systems A Dynamical Systems Approach to Machine Intelligence", Prentice-Hall of India New Delhi, June 1994.
Timothy J Ross, "Fuzzy Logic with Engineering Applications", McGraw-Hill, Inc, New York, 1997.
Laboratory Manual for Transmission line and fuzzy Trainer Kit of Electrical Engineering Department, NIT Warangal
SIM Power System User Guide Version 4 MATLAB Manual Periodicals and Conference Proceedings
S.M.Sadeghzadeh, M. Ehsan " Improvement of Transient Stability Limit in Power System Transmission Lines Using Fuzzy Control of FACTS Devices",IEEE Transactions on Power System Vol.13 No.3 ,August 1998
Chuen Chien Lee "Fuzzy Logic in Control Systems: Fuzzy Logic Controller", Part I and Part II. IEEE R. IEEE transactions on system, man, and cybernetics, vol.20 March/April11990
 A.M. Kulkarni, "Design of power system stabilizer for single-machine system using robust periodic output feedback controller", IEE Proceedings Part – C, Vol. 150, No. 2, pp. 211 – 216, March 2003. Technical Reports: Papers from Conference Proceedings unpublished)
U.Yolac, T.Talcinoz Dept. of Electronic Eng.Nigde 51200, Turkey "Comparison of Fuzzy Logic and PID Controls For TCSC Using MATLAB"
Jaun Dixon, Luis Moran, Jose Rodrfguz, Ricardo Domke, "Reactive power compensation technology state- of- art- review" (invited paper)
Electrical Engineering Dept Pontifica Universidad Catolica De CHILE.