Design of Power System Stabilizer with Neuro-Fuzzy UPFC Controller
The growth in the demand of electrical energy is
leading to load on the Power system which increases the occurrence
of frequent oscillations in the system. The reason for the oscillations
is due to the lack of damping torque which is required to dominate
the disturbances of Power system. By using FACT devices, such as
Unified Power Flow Controller (UPFC) can control power flow,
reduce sub-synchronous resonances and increase transient stability.
Hence, UPFC is used to damp the oscillations occurred in Power
system. This research focuses on adapting the neuro fuzzy controller
for the UPFC design by connecting the infinite bus (SMIB - Single
machine Infinite Bus) to a linearized model of synchronous machine
(Heffron-Phillips) in the power system. This model gains the
capability to improve the transient stability and to damp the
oscillations of the system.
[1] Gyugyl, “The Umfled Power Flow Controller. A New Approach to
Power Transmission Control”, IEEE Trmns on Power DehL wJy, Vol.
10, No.2, April 1995, pp.1085-1093.
[2] CD. Schauder, L. Gyugyl, M R Lund, D.M. Hamal, T R. Rletman. D.
RTorgerson, and A Edns, “Operation of the Unified Power Flow
Controller (UPFC) under Practical Constraints”, IEEE Trans. On Power
Delivery, Vol 13, No.2, Aprd 1998, pp 630-639.
[3] S. Limyingchal-oen, U, D. Annakkage, and NC. Pahalawaththa, “Effects
of Unified Power Flow Controllers on Transient Stability”, lEEE Proc -
GenerTrfm.rrn Distrlb , Vol. 145, No.2, March 1998, pp 182-188.
[4] Y. Morloka. M. Kate, Y. Mlshlma, and Y. Nakachi, “Implementation of
Undied Power Flow Controller and Verdicatlon for Transmm.lon
Capablhty Impl-ovement”, IEEE Trans on Power Systems, Vol. 14,
No.2, May 1999, pp.575-581.
[5] F.P. Demello and C. Concordia, “Concept of synchronous machine
stability as affected by excitation control”, IEEE Trans. PAS Vol. 88,
1969, pp 316-329.
[6] E.V. Larsen and D.A. Swann, “ Applying Power System Stabilizers”,
Part I- III, IEEE Trans. PAS Vol. 100, no 6, 1981, pp 3017-3046.
[7] P. Kundur, “Power System Stability and Control”, McGraw Hill
Inc.1993.
[8] Cheng S, Malik O.P., Hope G.S., “Design of self-tuning PID stabilizer
for a multi machine power system”, IEE Proceedings, Part C, 1986;
133(4), pp 176-185.
[9] Hsu Y.Y., Liou K.L., Hsu Y.Y, Cheng C.V., “Design of fuzzy power
system stabilizers for multi machine power systems ”, IEE Proceedings,
Part C,1990, 137(3).
[10] Y. Zhang, G.P. Chen, O.P. Malik and G.S. Hope, “An artificial neural
based adaptive power system stabilizer ”, IEEE Transactions on Energy
Conversion, Vol.8, No.1, March 1993, pp.71-77.
[11] Y.Zhang, O.P.Malik and G.P.Chen, “Artificial neural network power
system stabilizers in multi-machine power system environment ” , IEEE
Transactions on Energy Conversion, Vol. 10, No.1, March 1995,
pp.147-154
[12] J. R. Jang, “ANFIS: Adaptive-network-Based Fuzzy Inference System”,
IEEE Trans. Syst. Man Cybernetics, vol. 23, no.3, pp. 665-685, May
1993
[13] T. Takagi, and M. Sugeno, “Derivation of fuzzy control rules from
human operator’s control actions”, IFAC Symp. Fuzzy Inf. Knowledge
Repres. Dec. Analysis, pp. 55-60, 1983.
[14] E. M. Abdelrahim, and T. Yahagi, “A new transformed input-domain
ANFIS for highly nonlinear system modeling and prediction”, Electrical
and Computer Engineering, 2001. Canadian Conference on, vol. 1, pp.
655-660, 2001
[15] Jyh-Shing Roger Jang, Chuen-Tsai Sun, EijiMizutani, "Neuro-fuzzy and
soft computing: a computational approach to learning and machine
intelligence", Prentice-Hall, 1997
[16] Ravi Segala, Avdhesh Sharma, M.L. Kothari, “A self-tuning power
system stabilizer based on artificial neural network”, Electrical Power
and Energy Systems 26 (2004) 423-430
[1] Gyugyl, “The Umfled Power Flow Controller. A New Approach to
Power Transmission Control”, IEEE Trmns on Power DehL wJy, Vol.
10, No.2, April 1995, pp.1085-1093.
[2] CD. Schauder, L. Gyugyl, M R Lund, D.M. Hamal, T R. Rletman. D.
RTorgerson, and A Edns, “Operation of the Unified Power Flow
Controller (UPFC) under Practical Constraints”, IEEE Trans. On Power
Delivery, Vol 13, No.2, Aprd 1998, pp 630-639.
[3] S. Limyingchal-oen, U, D. Annakkage, and NC. Pahalawaththa, “Effects
of Unified Power Flow Controllers on Transient Stability”, lEEE Proc -
GenerTrfm.rrn Distrlb , Vol. 145, No.2, March 1998, pp 182-188.
[4] Y. Morloka. M. Kate, Y. Mlshlma, and Y. Nakachi, “Implementation of
Undied Power Flow Controller and Verdicatlon for Transmm.lon
Capablhty Impl-ovement”, IEEE Trans on Power Systems, Vol. 14,
No.2, May 1999, pp.575-581.
[5] F.P. Demello and C. Concordia, “Concept of synchronous machine
stability as affected by excitation control”, IEEE Trans. PAS Vol. 88,
1969, pp 316-329.
[6] E.V. Larsen and D.A. Swann, “ Applying Power System Stabilizers”,
Part I- III, IEEE Trans. PAS Vol. 100, no 6, 1981, pp 3017-3046.
[7] P. Kundur, “Power System Stability and Control”, McGraw Hill
Inc.1993.
[8] Cheng S, Malik O.P., Hope G.S., “Design of self-tuning PID stabilizer
for a multi machine power system”, IEE Proceedings, Part C, 1986;
133(4), pp 176-185.
[9] Hsu Y.Y., Liou K.L., Hsu Y.Y, Cheng C.V., “Design of fuzzy power
system stabilizers for multi machine power systems ”, IEE Proceedings,
Part C,1990, 137(3).
[10] Y. Zhang, G.P. Chen, O.P. Malik and G.S. Hope, “An artificial neural
based adaptive power system stabilizer ”, IEEE Transactions on Energy
Conversion, Vol.8, No.1, March 1993, pp.71-77.
[11] Y.Zhang, O.P.Malik and G.P.Chen, “Artificial neural network power
system stabilizers in multi-machine power system environment ” , IEEE
Transactions on Energy Conversion, Vol. 10, No.1, March 1995,
pp.147-154
[12] J. R. Jang, “ANFIS: Adaptive-network-Based Fuzzy Inference System”,
IEEE Trans. Syst. Man Cybernetics, vol. 23, no.3, pp. 665-685, May
1993
[13] T. Takagi, and M. Sugeno, “Derivation of fuzzy control rules from
human operator’s control actions”, IFAC Symp. Fuzzy Inf. Knowledge
Repres. Dec. Analysis, pp. 55-60, 1983.
[14] E. M. Abdelrahim, and T. Yahagi, “A new transformed input-domain
ANFIS for highly nonlinear system modeling and prediction”, Electrical
and Computer Engineering, 2001. Canadian Conference on, vol. 1, pp.
655-660, 2001
[15] Jyh-Shing Roger Jang, Chuen-Tsai Sun, EijiMizutani, "Neuro-fuzzy and
soft computing: a computational approach to learning and machine
intelligence", Prentice-Hall, 1997
[16] Ravi Segala, Avdhesh Sharma, M.L. Kothari, “A self-tuning power
system stabilizer based on artificial neural network”, Electrical Power
and Energy Systems 26 (2004) 423-430
@article{"International Journal of Electrical, Electronic and Communication Sciences:71276", author = "U. Ramesh Babu and V. Vijay Kumar Reddy and S. Tara Kalyani", title = "Design of Power System Stabilizer with Neuro-Fuzzy UPFC Controller", abstract = "The growth in the demand of electrical energy is
leading to load on the Power system which increases the occurrence
of frequent oscillations in the system. The reason for the oscillations
is due to the lack of damping torque which is required to dominate
the disturbances of Power system. By using FACT devices, such as
Unified Power Flow Controller (UPFC) can control power flow,
reduce sub-synchronous resonances and increase transient stability.
Hence, UPFC is used to damp the oscillations occurred in Power
system. This research focuses on adapting the neuro fuzzy controller
for the UPFC design by connecting the infinite bus (SMIB - Single
machine Infinite Bus) to a linearized model of synchronous machine
(Heffron-Phillips) in the power system. This model gains the
capability to improve the transient stability and to damp the
oscillations of the system.", keywords = "Power System, UPFC, (ANFIS) Adaptive Neuro
Fuzzy Inference System, transient, Low frequency oscillations.", volume = "8", number = "12", pages = "1952-4", }
