DocumentCode
1148247
Title
Decentralized power system stabilizer design using linear parameter varying approach
Author
Qiu, Wenzheng ; Vittal, Vijay ; Khammash, Mustafa
Author_Institution
Dept. of Electr. & Comput. Eng., Iowa State Univ., Ames, IA, USA
Volume
19
Issue
4
fYear
2004
Firstpage
1951
Lastpage
1960
Abstract
In this paper, the power system model is formulated as a finite dimensional linear system whose state-space entries depend continuously on a time varying parameter vector called the scheduling variables. This system is referred to as the linear parameter varying (LPV) system. Although the trajectory of the changing parameters such as load levels and tie line flows is not known in advance, in most situations, they can be measured in real time. The LPV technique is applied to the decentralized design of power system stabilizers (PSS) for large systems. In the approach developed, instead of considering the complete system model with all the interconnections, we develop a decentralized approach where each individual machine is considered separately with arbitrarily changing real and reactive power output in a defined range. These variables are chosen as the scheduling variables. The designed controller automatically adjusts its parameters depending on the scheduling variables to coordinate with change of operating conditions and the dynamics of the rest of the system. The resulting decentralized PSSs give good performance in a large operating range. Design procedures are presented and comparisons are made between the LPV decentralized PSSs and conventionally designed PSSs on the 50-generator IEEE test system.
Keywords
control system synthesis; decentralised control; linear systems; multidimensional systems; power system interconnection; power system stability; scheduling; time-varying systems; decentralized power system; finite dimensional linear system; large system; linear parameter varying approach; power system stabilizer; scheduling variable; time varying parameter vector; Automatic control; Control systems; Linear systems; Power system interconnection; Power system measurements; Power system modeling; Power systems; Reactive power; Time varying systems; Vectors; 65; Decentralized control; LPV; gain scheduling; oscillation damping; power system stabilizer;
fLanguage
English
Journal_Title
Power Systems, IEEE Transactions on
Publisher
ieee
ISSN
0885-8950
Type
jour
DOI
10.1109/TPWRS.2004.836269
Filename
1350835
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