Abstract
With the technical development and cost reduction of power electronics, more and more FACTS devices are being applied into power system especially into modern power system toward smart grid [1–3]. FACTS devices can conveniently adjust network parameters (e.g., reactance) flexibly and benefit power flow optimization, transmitted power increase, bus voltage stability enhancement, and so on. At the same time, with more and more application of synchronized phasor measurement (PMU) technology, WAMS technology are being applied into power system, which is also one obvious technical feature of the coming smart grid [4–6]. Therefore, it would be wonderful to construct WAMS-based FACTS supplementary wide-area damping control strategy, that combines the quick and flexible control ability of FACTS devices and the global monitoring ability of WAMS, to prevent the low-frequency oscillation (especial the inter-area oscillation) and enhance the global stability of power system.
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References
Bose A (2010) New smart grid applications for power system operations. In: IEEE power and energy society general meeting, 2010
Zarghami M, Crow ML, Jagannathan S (2010) Nonlinear control of FACTS controllers for damping interarea oscillations in power systems. IEEE Trans Power Delivery 25(4):3113–3123
Eriksson R, Soder L (2011) Wide-area measurement system-based subspace identification for obtaining linear models to centrally coordinate controllable devices. IEEE Trans Power Delivery 26(2):988–997
Bose A (2010) Smart transmission grid applications and their supporting infrastructure. IEEE Trans Smart Grid 1(1):11–19
De La Ree J, Centeno V, Thorp JS, Phadke AG (2010) Synchronized phasor measurement applications in power systems. IEEE Trans Smart Grid 1(1):20–27
Chakrabortty A, Chow JH, Salazar A (2011) A measurement-based framework for dynamic equivalencing of large power systems using wide-area phasor measurements. IEEE Trans Smart Grid 2(1):68–81
Demello FP, Concordia C (1969) Concepts of synchronous machine stability as affected by excitation control. IEEE Trans Power Apparatus Syst 88(4):316–329
Cai LJ, Erilich I (2005) Simultaneous coordinated tuning of PSS and FACTS damping controllers in large power systems. IEEE Trans Power Syst 20(1):294–300
Gupta R, Bandyopadhyay B, Kulkarni AM (2005) Power system stabiliser for multimachine power system using robust decentralised periodic output feedback. IEE Proc Control Theory Appl 152(1):3–8
Zhang Y, Bose A (2008) Design of wide-area damping controllers for interarea oscillations. IEEE Trans Power Syst 23(3):1136–1143
Kutzner R, Scholz B, Reimann M (2003) An advanced model-based approach to stabilize power system oscillations based on the H-infinite theory modelling and tuning guide, practical experience. In: IEEE power engineering society general meeting, 2003
Zhu CL, Zhou RJ, Wang YY (1998) A new decentralized nonlinear voltage controller for multimachine power systems. IEEE Trans Power Syst 13(1):211–216
Grcar SV, Kumar SVJ, Yadaiah N (2004) Control strategies for transient stability of multimachine power systems-a comparison. In: IEEE international conference on power system technology, 2004
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Li, Y., Yang, D., Liu, F., Cao, Y., Rehtanz, C. (2016). Basic Framework and Operating Principle of Wide-Area Damping Control. In: Interconnected Power Systems. Power Systems. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-662-48627-6_6
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DOI: https://doi.org/10.1007/978-3-662-48627-6_6
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