State Estimation in Electric Power Systems Leveraging Graph Neural
Networks
- URL: http://arxiv.org/abs/2201.04056v1
- Date: Tue, 11 Jan 2022 16:58:20 GMT
- Title: State Estimation in Electric Power Systems Leveraging Graph Neural
Networks
- Authors: Ognjen Kundacina, Mirsad Cosovic, Dejan Vukobratovic
- Abstract summary: This paper proposes training a graph neural network (GNN) to learn the estimates given the PMU voltage and current measurements as inputs.
GNN is trained using synthetic datasets, created by randomly sampling sets of measurements in the power system.
The presented results display the accuracy of GNN predictions in various test scenarios and tackle the sensitivity of the predictions to the missing data.
- Score: 1.2891210250935146
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: The goal of the state estimation (SE) algorithm is to estimate complex bus
voltages as state variables based on the available set of measurements in the
power system. Because phasor measurement units (PMUs) are increasingly being
used in transmission power systems, there is a need for a fast SE solver that
can take advantage of PMU high sampling rates. This paper proposes training a
graph neural network (GNN) to learn the estimates given the PMU voltage and
current measurements as inputs, with the intent of obtaining fast and accurate
predictions during the evaluation phase. GNN is trained using synthetic
datasets, created by randomly sampling sets of measurements in the power system
and labelling them with a solution obtained using a linear SE with PMUs solver.
The presented results display the accuracy of GNN predictions in various test
scenarios and tackle the sensitivity of the predictions to the missing input
data.
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