Recursive Dynamic State Estimation for Power Systems with an Incomplete Nonlinear DAE Model

Power systems are highly-complex, large-scale engineering systems subject to many uncertainties, which makes accurate mathematical modeling challenging. This paper proposes a novel, centralized dynamic state estimator for power systems that lack models of some components. Including the available dynamic evolution equations, algebraic network equations, and phasor measurements, we apply the least squares criterion to estimate all dynamic and algebraic states recursively. This approach results in an algorithm that generalizes the iterated extended Kalman filter and does not require static network observability. We further derive a graph theoretic condition to guarantee estimability for the proposed approach. A numerical study evaluates the performance under short circuits in the network and load changes for three different discretization schemes. The results show superior tracking performance compared to robust two-stage procedures within computational times that are feasible for real-time application.