| Title |
A Practical Exciter Model Reduction Approach For Power System Transient Stability Simulation |
| DOI |
http://dx.doi.org/10.5207/JIEIE.2015.29.10.089 |
| Keywords |
Power System Transient Stability Simulation, Explicit Numerical Integration Method, Numerical Integration Time Step, Computational Efficiency, Exciter Model Complexity Reduction, EXST1 |
| Abstract |
Explicit numerical integration methods for power system transient stability simulation require very small time steps to avoid numerical instability. The EXST1 exciter model is a primary source of fast dynamics in power system transients. In case of the EXST1, the required small integration time step for entire system simulation increases the computational demands in terms of running time and storage. This paper presents a practical exciter model reduction approach which allows the increase of the required step size and thus the method can decrease the computational demands. The fast dynamics in the original EXST1 are eliminated in the reduced exciter model. The use of a larger time step improves the computational efficiency. This paper describes the way to eliminate the fast dynamics from the original exciter model based on linear system theory. In order to validate the performance of the proposed method, case studies with the GSO-37 bus system are provided. Comparisons between the original and reduced models are made in simulation accuracy and critical clearing time. |