TY - GEN
T1 - A circuit-theoretic approach to state estimation
AU - Li, Shimiao
AU - Pandey, Amritanshu
AU - Kar, Soummya
AU - Pileggi, Larry
N1 - Publisher Copyright:
© 2020 IEEE.
PY - 2020/10/26
Y1 - 2020/10/26
N2 - Traditional state estimation (SE) methods that are based on nonlinear minimization of the sum of localized measurement error functionals are known to suffer from non-convergence and large residual errors. In this paper we propose an equivalent circuit formulation (ECF)-based SE approach that inherently considers the complete network topology and associated physical constraints. We analyze the mathematical differences between the two approaches and show that our approach produces a linear state-estimator that is mathematically a quadratic programming (QP) problem with closed-form solution. Furthermore, this formulation imposes additional topology-based constraints that provably shrink the feasible region and promote convergence to a more physically meaningful solution. From a probabilistic viewpoint, we show that our method applies prior knowledge into the estimate, thus converging to a more physics-based estimate than the traditional observation-driven maximum likelihood estimator (MLE). Importantly, incorporation of the entire system topology and underlying physics, while being linear, makes ECF-based SE advantageous for large-scale systems.
AB - Traditional state estimation (SE) methods that are based on nonlinear minimization of the sum of localized measurement error functionals are known to suffer from non-convergence and large residual errors. In this paper we propose an equivalent circuit formulation (ECF)-based SE approach that inherently considers the complete network topology and associated physical constraints. We analyze the mathematical differences between the two approaches and show that our approach produces a linear state-estimator that is mathematically a quadratic programming (QP) problem with closed-form solution. Furthermore, this formulation imposes additional topology-based constraints that provably shrink the feasible region and promote convergence to a more physically meaningful solution. From a probabilistic viewpoint, we show that our method applies prior knowledge into the estimate, thus converging to a more physics-based estimate than the traditional observation-driven maximum likelihood estimator (MLE). Importantly, incorporation of the entire system topology and underlying physics, while being linear, makes ECF-based SE advantageous for large-scale systems.
KW - Equivalent circuit formulation
KW - Phasor measurement units
KW - Power system measurements
KW - Power system modeling
KW - State estimation
UR - https://www.scopus.com/pages/publications/85097328177
U2 - 10.1109/ISGT-Europe47291.2020.9248872
DO - 10.1109/ISGT-Europe47291.2020.9248872
M3 - Conference contribution
AN - SCOPUS:85097328177
T3 - IEEE PES Innovative Smart Grid Technologies Conference Europe
SP - 1126
EP - 1130
BT - Proceedings of 2020 IEEE PES Innovative Smart Grid Technologies Europe, ISGT-Europe 2020
PB - IEEE Computer Society
T2 - 10th IEEE PES Innovative Smart Grid Technologies Europe, ISGT-Europe 2020
Y2 - 26 October 2020 through 28 October 2020
ER -