Fankun Bu scite author profile

This paper presents a review of the literature on State Estimation (SE) in power systems. While covering some works related to SE in transmission systems, the main focus of this paper is Distribution System State Estimation (DSSE). The paper discusses a few critical topics of DSSE, including mathematical problem formulation, application of pseudomeasurements, metering instrument placement, network topology issues, impacts of renewable penetration, and cyber-security. Both conventional and modern data-driven and probabilistic techniques have been reviewed. This paper can provide researchers and utility engineers with insights into the technical achievements, barriers, and future research directions of DSSE.

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A Time-Series Distribution Test System Based on Real Utility Data

Yuan

Wang

et al. 2019

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In this paper, we provide a time-series distribution test system. This test system is a fully observable distribution grid in Midwest U.S. with smart meters (SM) installed at all end users. Our goal is to share a real U.S. distribution grid model without modification. This grid model is comprehensive and representative since it consists of both overhead lines and underground cables, and it has standard distribution grid components such as capacitor banks, line switches, substation transformers with load tap changer and secondary distribution transformers. An important uniqueness of this grid model is it has one-year smart meter measurements at all nodes, thus bridging the gap between existing test feeders and quasi-static time-series based distribution system analysis.

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A Data-Driven Game-Theoretic Approach for Behind-the-Meter PV Generation Disaggregation

Dehghanpour

Yuan

et al. 2020

IEEE Trans. Power Syst.

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Rooftop solar photovoltaic (PV) power generator is a widely used distributed energy resource (DER) in distribution systems. Currently, the majority of PVs are installed behindthe-meter (BTM), where only customers' net demand is recorded by smart meters. Disaggregating BTM PV generation from net demand is critical to utilities for enhancing grid-edge observability. In this paper, a data-driven approach is proposed for BTM PV generation disaggregation using solar and demand exemplars. First, a data clustering procedure is developed to construct a library of candidate load/solar exemplars. To handle the volatility of BTM resources, a novel game-theoretic learning process is proposed to adaptively generate optimal composite exemplars using the constructed library of candidate exemplars, through repeated evaluation of disaggregation residuals. Finally, the composite native demand and solar exemplars are employed to disaggregate solar generation from net demand using a semisupervised source separator. The proposed methodology has been verified using real smart meter data and feeder models.

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A Game-Theoretic Data-Driven Approach for Pseudo-Measurement Generation in Distribution System State Estimation

Dehghanpour

Yuan

Wang

et al. 2019

IEEE Trans. Smart Grid

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In this paper, we present an efficient computational framework with the purpose of generating weighted pseudomeasurements to improve the quality of Distribution System State Estimation (DSSE) and provide observability with Advanced Metering Infrastructure (AMI) against unobservable customers and missing data. The proposed technique is based on a gametheoretic expansion of Relevance Vector Machines (RVM). This platform is able to estimate the customer power consumption data and quantify its uncertainty while reducing the prohibitive computational burden of model training for large AMI datasets. To achieve this objective, the large training set is decomposed and distributed among multiple parallel learning entities. The resulting estimations from the parallel RVMs are then combined using a game-theoretic model based on the idea of repeated games with vector payoff. It is observed that through this approach and by exploiting the seasonal changes in customers' behavior the accuracy of pseudo-measurements can be considerably improved, while introducing robustness against bad training data samples. The proposed pseudo-measurement generation model is integrated into a DSSE using a closed-loop information system, which takes advantage of a Branch Current State Estimator (BCSE) data to further improve the performance of the designed machine learning framework. This method has been tested on a practical distribution feeder model with smart meter data for verification.

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Distributed Optimal Conservation Voltage Reduction in Integrated Primary-Secondary Distribution Systems

Zhang

Guo

Wang

et al. 2021

IEEE Trans. Smart Grid

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Fankun Bu

A Survey on State Estimation Techniques and Challenges in Smart Distribution Systems

A Time-Series Distribution Test System Based on Real Utility Data

A Data-Driven Game-Theoretic Approach for Behind-the-Meter PV Generation Disaggregation

A Game-Theoretic Data-Driven Approach for Pseudo-Measurement Generation in Distribution System State Estimation

Distributed Optimal Conservation Voltage Reduction in Integrated Primary-Secondary Distribution Systems

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