Time Synchronized State Estimation for Incompletely Observed Distribution Systems Using Deep Learning Considering Realistic Measurement Noise

• URL: http://arxiv.org/abs/2011.04272v2
• Date: Tue, 9 Feb 2021 19:15:26 GMT
• Title: Time Synchronized State Estimation for Incompletely Observed Distribution Systems Using Deep Learning Considering Realistic Measurement Noise
• Authors: Behrouz Azimian, Reetam Sen Biswas, Anamitra Pal, Lang Tong
• Abstract summary: Time-synchronized state estimation is a challenge for distribution systems because of limited real-time observability. This paper formulates a deep learning (DL)-based approach to perform unbalanced three-phase distribution system state estimation.
• Score: 1.7587442088965226
• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: Time-synchronized state estimation is a challenge for distribution systems because of limited real-time observability. This paper addresses this challenge by formulating a deep learning (DL)-based approach to perform unbalanced three-phase distribution system state estimation (DSSE). Initially, a data-driven approach for judicious measurement selection to facilitate reliable state estimation is provided. Then, a deep neural network (DNN) is trained to perform DSSE for systems that are incompletely observed by synchrophasor measurement devices (SMDs). Robustness of the proposed methodology is demonstrated by considering realistic measurement error models for SMDs. A comparative study of the DNN-based DSSE with classical linear state estimation indicates that the DL-based approach gives better accuracy with a significantly smaller number of SMDs.

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