International Journal of Electrical Communication Engineering

It is well known that the combustion of fossil fuels in an electrical power plant has a huge effect on the global atmosphere as a consequence of greenhouse gases. In several nations, the usage of cost-effective and efficient low-carbon energy sources is becoming a significant energy strategy. Among the numerous forms of clean energy resources–such as solar power, hydropower, ocean wave power, and so on–wind power is currently the fastest-growing form of renewable energy.

Keywords: ASGWT, DFIG, FACTS controllers, FSGWT, SSIGE, wind farms

Moharana A, Varma RK, Seethapathy R. SSR alleviation by STATCOM in induction-generator-based wind farm connected to series compensated line. IEEE Trans Sustain Energy. July 2014;5(3):947–57. doi: 10.1109/TSTE.2014.2311072.

Golshannavaz S, Mokhtari M, Nazarpour D. SSR suppression via STATCOM in series compensated wind farm integrations. Electr Eng (ICEE) 19th Iranian Conference on, May 2011; 2011.

El-Moursi MS, Bak-Jensen B, Abdel-Rahman MH. Novel STATCOM controller for mitigating SSR and damping power system oscillations in a series compensated wind park. IEEE Trans Power Electron. February 2010;25(2), pp.429,441. doi: 10.1109/TPEL.2009.2026650.

Moharana RKV, Seethapathy R. SSR mitigation in wind farm connected to series compensated transmission line using STATCOM. Power Electron Mach Wind Appl (PEMWA). 2012. IEEE, July 16–18 2012.

Abdou F, Abu-Siada A, Pota HR. Damping of subsynchronous oscillations and improve transient stability for wind farms. Innov Smart Grid Technol Asia (ISGT). 2011. IEEE. Pes; November 13–16 2011.

Varma RK, Auddy S. Mitigation of subsynchronous oscillations in a series compensated wind farm with static var compensator General Meeting. Power: Engineering Society; 2006. IEEE, 2006.

Boopathi VP, Muzamil Ahamed R, Kumudini Devi RP, Ramanujam R. Analysis and mitigation of subsynchronous oscillations in a radially-connected wind farm Power and Energy Systems Conference: towards. Sustain Energy. 2014, March;2014.

Anju M, Rajasekaran R. Co-ordination of SMES with STATCOM for mitigating SSR and damping power system oscillations in a series compensated wind power system. Computer communication and informatics (ICCCI) International Conference on, Jan. 2013; 2013.

Karaagac U, Faried SOO, Mahseredjian J, Edris A. Coordinated control of wind energy conversion systems for mitigating subsynchronous interaction in DFIG-based wind farms. IEEE Trans Smart

Grid. September 2014;5(5):2440–9. doi: 10.1109/TSG.2014.2330453.

Leon E, Solsona JA. Sub-synchronous interaction damping control for DFIG wind turbines. IEEE Trans Power Syst, vol. pp, no.99. June 2014;70:1–10.

Wang L, Thi MS. Stability analysis of four PMSG-based offshore wind farms fed to an SG-based power system through an LCC-HVDC link. IEEE Trans Ind Electron. June 2013;60(6):2392–400. doi: 10.1109/TIE.2012.2227904.

Akagi H, Sato H. Control and performance of a doubly fed induction machine intended for a flywheel energy storage system. IEEE Trans Power Electron. January 2002;17(1), pp. 109–116. doi: 10.1109/63.988676.

Pena R, Clare JC, Asher GM. A doubly fed induction generator using back-to-back PWM converters supplying an isolated load from a variable speed wind turbine. IEE Proc Electr Power Appl. 1996;143(5). 380–387. doi: 10.1049/ip-epa:19960454.

Rahimi M, Parniani M. Efficient control scheme of wind turbines with doubly fed induction generators for low voltage ride-through capability enhancement. IET Renew Power Gener. May 2010;4(3), pp. 242–252. doi: 10.1049/iet-rpg.2009.0072.

Ledesma P, Usaola J. Effect of neglecting stator transients in doubly fed induction generators models. IEEE Trans On Energy Conversion. June 2004;19(2), pp. 459–461. doi: 10.1109/TEC.2004.827045.

Arbi J, Ghorbal MJ-B, Slama-Belkhodja I, Charaabi L. Direct virtual torque control for doubly fed induction generator grid connection. IEEE Trans Ind Electron. October 2009;56(10), pp. 4163–4173. doi: 10.1109/TIE.2009.2021590.

Tremblay E, Atayde S, Chandra A. Comparative study of control strategies for the doubly fed induction generator in wind energy conversion systems: a DSP-based Implementation approach. IEEE Trans Sustain Energy. July 2011;2(3). 288–299. doi: 10.1109/TSTE.2011.2113381.

Abad G, Rodriguez MA, Poza J. Two-level VSC based predictive direct torque control of the doubly fed induction machine with reduced torque and flux ripples at low constant switching frequency. IEEE Trans Power Electron. May 2008;23(3), pp.1050–1060. doi: 10.1109/TPEL.2008.921160.

Abad G, Rodriguez MA, Iwanski G, Poza J. Direct power control of doubly fed induction- generator-based wind turbines under unbalanced grid voltage. IEEE Trans Power Electron. February 2010;25(2), pp. 442–452. doi: 10.1109/TPEL.2009.2027438.

Santos-Martin D, Rodriguez-Amenedo JL, Arnalte S. Direct power control applied to doubly fed induction generator under unbalanced grid voltage conditions. IEEE Trans Power Electron. September 2008;23(5). 2328–2336. doi: 10.1109/TPEL.2008.2001907.

Xu L, Cartwright P. Direct active and reactive power control of DFIG for wind energy generation. IEEE Trans On Energy Conversion. September 2006;21(3), pp. 750–758. doi: 10.1109/TEC.2006.875472.

Tazil M, Kumar V, Bansal RC, Kong S, Dong ZY, Freitas W. Three-phase doubly fed induction generators: an overview. IET Electr Power Appl. February 2010;4(2). 75–89. doi: 10.1049/iet-epa.2009.0071.

Datta R, Ranganathan VT. Direct power control of grid-connected

wound rotor induction machine without rotor position sensors. IEEE Trans Power Electron. May 2001;16(3), pp. 390–399. doi: 10.1109/63.923772.

Tohidi S, Oraee H, Zolghadri MR, Shao S, Tavner P. Analysis and enhancement of low-voltage ride-through capability of brushless doubly fed induction generator. IEEE Trans Ind Electron. March 2013;60(3), pp. 1146–1155. doi: 10.1109/TIE.2012.2190955.

Mei F, Pal BC. Modeling of doubly fed induction generator for power system stability study. In: Proceedings of the IEEE power & energy general meeting 2008, Pittsburgh; Juil 2008.

Mei F, Pal BC. Modeling adequacy of the doubly fed induction generator for small-signal stability studies in power systems. IET Renew Power Gener. September 2008;2(3), pp. 181–190.

Lara OA, Jenkins N, Ekanayake J, Cartwright P, Hughes M. Wind energy generation modeling and control. England: John Wiley & Sons; 2009.

Lei Y, Mullane A, Lightbody G, Yacamini R. Modeling of the wind turbine with a doubly fed induction generator for grid integration studies. IEEE Trans On Energy Conversion. March 2006;21(1):257–64. doi: 10.1109/TEC.2005.847958.

Klee H, Allen R. Simulation of dynamic systems with MATLAB and SIMULINK, Tylor & Francis Group. 2nd ed. Boca Raton, FL; 2011.

Anderson PM, Agrawal BL, Van Less JE. Sub-synchronous resonance in power systems. New York: IEEE Publications; 1990.

Lubonsy Z. Wind turbine operation in electric power systems. New York: Springer; 2010.

Ulf HÃd’ger. Christian Rehtanz, monitoring, control and protection of

interconnected power systems. Springer; 2014.