Biblio

Online Dynamic Security Assessment (DSA) is a dynamical system widely used for assessing and analyzing an electrical power system. The outcomes of DSA are used in many aspects of the operation of power system, from monitoring the system to determining remedial action schemes (e.g. the amount of generators to be shed at the event of a fault). Measurement from supervisory control and data acquisition (SCADA) and state estimation (SE) results are the inputs for online-DSA, however, the SE error, caused by sudden change in power flow or low convergence rate, could be unnoticed and skew the outcome. Therefore, generator shedding scheme cannot achieve optimum but must have some margin because we don't know how SE error caused by these problems will impact power system stability control. As a method for solving the problem, we developed SE error detection system (EDS), which is enabled by detecting the SE error that will impact power system transient stability. The method is comparing a threshold value and an index calculated by the difference between SE results and PMU observation data, using the distance from the fault point and the power flow value. Using the index, the reliability of the SE results can be verified. As a result, online-DSA can use the SE results while avoiding the bad SE results, assuring the outcome of the DSA assessment and analysis, such as the amount of generator shedding in order to prevent the power system's instability.

In this work we investigate existing and new metrics for evaluating transient stability of power systems to quantify the impact of distributed control schemes. Specifically, an energy storage system (ESS)-based control scheme that builds on feedback linearization theory is implemented in the power system to enhance its transient stability. We study the value of incorporating such ESS-based distributed control on specific transient stability metrics that include critical clearing time, critical control activation time, system stability time, rotor angle stability index, rotor speed stability index, rate of change of frequency, and control power. The stability metrics are evaluated using the IEEE 68-bus test power system. Numerical results demonstrate the value of the distributed control scheme in enhancing the transient stability metrics of power systems.

In this work we investigate existing and new metrics for evaluating transient stability of power systems to quantify the impact of distributed control schemes. Specifically, an energy storage system (ESS)-based control scheme that builds on feedback linearization theory is implemented in the power system to enhance its transient stability. We study the value of incorporating such ESS-based distributed control on specific transient stability metrics that include critical clearing time, critical control activation time, system stability time, rotor angle stability index, rotor speed stability index, rate of change of frequency, and control power. The stability metrics are evaluated using the IEEE 68-bus test power system. Numerical results demonstrate the value of the distributed control scheme in enhancing the transient stability metrics of power systems.

In interconnected power systems, dynamic model reduction can be applied to generators outside the area of interest (i.e., study area) to reduce the computational cost associated with transient stability studies. This paper presents a method of deriving the reduced dynamic model of the external area based on dynamic response measurements. The method consists of three steps, namely dynamic-feature extraction, attribution, and reconstruction (DEAR). In this method, a feature extraction technique, such as singular value decomposition (SVD), is applied to the measured generator dynamics after a disturbance. Characteristic generators are then identified in the feature attribution step for matching the extracted dynamic features with the highest similarity, forming a suboptimal “basis” of system dynamics. In the reconstruction step, generator state variables such as rotor angles and voltage magnitudes are approximated with a linear combination of the characteristic generators, resulting in a quasi-nonlinear reduced model of the original system. The network model is unchanged in the DEAR method. Tests on several IEEE standard systems show that the proposed method yields better reduction ratio and response errors than the traditional coherency based reduction methods.
 

In this paper, parallelization and high performance computing are utilized to enable ultrafast transient stability analysis that can be used in a real-time environment to quickly perform “what-if” simulations involving system dynamics phenomena. EPRI's Extended Transient Midterm Simulation Program (ETMSP) is modified and enhanced for this work. The contingency analysis is scaled for large-scale contingency analysis using Message Passing Interface (MPI) based parallelization. Simulations of thousands of contingencies on a high performance computing machine are performed, and results show that parallelization over contingencies with MPI provides good scalability and computational gains. Different ways to reduce the Input/Output (I/O) bottleneck are explored, and findings indicate that architecting a machine with a larger local disk and maintaining a local file system significantly improve the scaling results. Thread-parallelization of the sparse linear solve is explored also through use of the SuperLU_MT library.