Physics-Guided Deep Neural Networks for Power Flow Analysis

Xinyue Hu; Haoji Hu; Saurabh Verma; Zhi Li Zhang

doi:10.1109/TPWRS.2020.3029557

Physics-Guided Deep Neural Networks for Power Flow Analysis

Xinyue Hu, Haoji Hu, Saurabh Verma, Zhi Li Zhang

Computer Science and Engineering

Research output: Contribution to journal › Article › peer-review

69 Scopus citations

Abstract

Solving power flow (PF) equations is the basis of power flow analysis, which is important in determining the best operation of existing systems, performing security analysis, etc. However, PF equations can be out-of-date or even unavailable due to system dynamics, and uncertainties, making traditional numerical approaches infeasible. To address these concerns, researchers have proposed data-driven approaches to solve the PF problem by learning the mapping rules from historical system operation data. Nevertheless, prior data-driven approaches suffer from poor performance, and generalizability, due to overly simplified assumptions of the PF problem or ignorance of physical laws governing power systems. In this paper, we propose a physics-guided neural network to solve the PF problem, with an auxiliary task to rebuild the PF model. By encoding different granularity of Kirchhoff's laws, and system topology into the rebuilt PF model, our neural-network based PF solver is regularized by the auxiliary task, and constrained by the physical laws. The simulation results show that our physics-guided neural network methods achieve better performance, and generalizability compared to existing unconstrained data-driven approaches. Furthermore, we demonstrate that the weight matrices of the proposed neural networks embody power system physics by showing their similarities with the bus admittance matrices.

Original language	English (US)
Article number	9216092
Pages (from-to)	2082-2092
Number of pages	11
Journal	IEEE Transactions on Power Systems
Volume	36
Issue number	3
DOIs	https://doi.org/10.1109/TPWRS.2020.3029557
State	Published - May 2021

Bibliographical note

Funding Information:
Manuscript received March 19, 2020; revised July 28, 2020; accepted September 27, 2020. Date of publication October 7, 2020; date of current version April 19, 2021. This work was supported in part by NSF under Grants CNS-1814322, CNS-1831140, CNS-1901103, and CNS-1952085, in part by US DoD DTRA DTRA under Grant HDTRA1-14-1-0040, and in part by an Amazon AWS ML Research Award. Paper no. TPWRS-00427-2020. (Corresponding author: Xinyue Hu.) The authors are with the Department of Computer Science and Engineering, University of Minnesota, Minneapolis, MN 55455, United States (e-mail: hu000007@umn.edu; huxxx899@umn.edu; verma076@umn.edu; zhzhang@cs.umn.edu).

Publisher Copyright:
© 1969-2012 IEEE.

Keywords

Power flow analysis
data-driven analysis
neural networks
physics-guided learning
power flow solver

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title = "Physics-Guided Deep Neural Networks for Power Flow Analysis",

abstract = "Solving power flow (PF) equations is the basis of power flow analysis, which is important in determining the best operation of existing systems, performing security analysis, etc. However, PF equations can be out-of-date or even unavailable due to system dynamics, and uncertainties, making traditional numerical approaches infeasible. To address these concerns, researchers have proposed data-driven approaches to solve the PF problem by learning the mapping rules from historical system operation data. Nevertheless, prior data-driven approaches suffer from poor performance, and generalizability, due to overly simplified assumptions of the PF problem or ignorance of physical laws governing power systems. In this paper, we propose a physics-guided neural network to solve the PF problem, with an auxiliary task to rebuild the PF model. By encoding different granularity of Kirchhoff's laws, and system topology into the rebuilt PF model, our neural-network based PF solver is regularized by the auxiliary task, and constrained by the physical laws. The simulation results show that our physics-guided neural network methods achieve better performance, and generalizability compared to existing unconstrained data-driven approaches. Furthermore, we demonstrate that the weight matrices of the proposed neural networks embody power system physics by showing their similarities with the bus admittance matrices.",

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note = "Funding Information: Manuscript received March 19, 2020; revised July 28, 2020; accepted September 27, 2020. Date of publication October 7, 2020; date of current version April 19, 2021. This work was supported in part by NSF under Grants CNS-1814322, CNS-1831140, CNS-1901103, and CNS-1952085, in part by US DoD DTRA DTRA under Grant HDTRA1-14-1-0040, and in part by an Amazon AWS ML Research Award. Paper no. TPWRS-00427-2020. (Corresponding author: Xinyue Hu.) The authors are with the Department of Computer Science and Engineering, University of Minnesota, Minneapolis, MN 55455, United States (e-mail: hu000007@umn.edu; huxxx899@umn.edu; verma076@umn.edu; zhzhang@cs.umn.edu). Publisher Copyright: {\textcopyright} 1969-2012 IEEE.",

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Physics-Guided Deep Neural Networks for Power Flow Analysis

Abstract

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Keywords

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