Article ID | Journal | Published Year | Pages | File Type |
---|---|---|---|---|
399842 | International Journal of Electrical Power & Energy Systems | 2013 | 9 Pages |
To ensure the small-signal stability of a power system, power system stabilizers (PSSs) are extensively applied for damping low frequency power oscillations through modulating the excitation supplied to synchronous machines, and increasing interest has been focused on developing different PSS schemes to tackle the threat of damping oscillations to power system stability. This paper examines four different PSS models and investigates their performances on damping power system dynamics using both small-signal eigenvalue analysis and large-signal dynamic simulations. The four kinds of PSSs examined include the Conventional PSS (CPSS), Single Neuron based PSS (SNPSS), Adaptive PSS (APSS) and Multi-band PSS (MBPSS). A steep descent parameter optimization algorithm is employed to seek the optimal PSS design parameters. To evaluate the effects of these PSSs on improving power system dynamic behaviors, case studies are carried out on an 8-unit 24-bus power system through both small-signal eigenvalue analysis and large-signal time-domain simulations.
► Four different power system stabilizers (PSSs) are examined. ► The steepest descent method is employed to seek the optimal PSS parameters. ► Probabilistic eigenvalue analysis and dynamic simulations are implemented. ► The effects of four PSSs on improving power system performances are compared.