Robust State Estimation Model for Low Voltage Distribution Networks in the Presence of Multiple Gross Errors

Distribution network state inference refers to the process of calculating the state variables of each node by using measurement data and network models in the operation of the distribution system. However, the uneven measurement layout and insufficient measurement accuracy in the distribution network have brought great challenges to the state inference of the distribution network. This paper proposes a low-observable distribution network state inference method based on a graph convolution network (GCN), which uses sparse measurement data to infer missing measurement information. Firstly, the observability of the distribution network is analyzed by the numerical probability analysis method. Secondly, the GCN is employed to extract feature information from measurement data and integrate these features. The state inference model of the distribution network based on the GCN is established. Subsequently, power flow constraints of the distribution network are incorporated into the GCN training process to enhance the precision of the generated data. Ultimately, the efficacy of the proposed method is validated using the IEEE 33-node distribution system.

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Least Absolute Value-Based Temperature-Dependent Robust State Estimation

Park,

Kang,

Kim

et al. 2024

IEEE Access

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Inaccuracies in both measurements and parameter determination can generate biased results in state estimation. The change in branch temperature precipitates fluctuations in resistance and branch flow measurements. Even when flow measurements derived from remote terminal units are precise, the erroneous resistance value can still render the estimation results inaccurate. In this paper, we propose a least absolute value based, temperature-dependent, static state estimation method. The proposed method is formulated as a linear programming, employing an L1 norm objective function and introducing a branch temperature with the expanded Jacobian to consider thermal inertia. The proposed estimator not only estimates the state but also estimates branch temperature along with the resistance. Therefore, our proposed method captures the accurate system states robust against the parameter error and measurement error. Furthermore, the proposed estimator can evaluate thermal inertia with higher accuracy compared to the existing method. The case studies illustrate the robustness of the proposed method against parameter and measurement inaccuracies. Additionally, it can estimate state and thermal inertia more effectively than the comparative estimator.INDEX TERMS Branch temperature, least absolute value, power system state estimation, thermal inertia.

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Robust State Estimation Model for Low Voltage Distribution Networks in the Presence of Multiple Gross Errors

Cited by 3 publications

References 54 publications

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Securing the green grid: A data anomaly detection method for mitigating cyberattacks on smart meter measurements

State inference for low-observable distribution system based on graph convolutional network

Least Absolute Value-Based Temperature-Dependent Robust State Estimation

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