Physics-Aware Neural Dynamic Equivalence of Power Systems

Qing Shen; Yifan Zhou; Qiang Zhang; Slava Maslennikov; Xiaochuan Luo; Peng Zhang

doi:10.1109/TPWRS.2023.3328162

Physics-Aware Neural Dynamic Equivalence of Power Systems

Qing Shen
, Yifan Zhou
, Qiang Zhang
, Slava Maslennikov
, Xiaochuan Luo
, Peng Zhang

Stony Brook University

Stony Brook University
ISO New England Inc.

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

12 Scopus citations

Abstract

This letter devises Neural Dynamic Equivalence (NeuDyE), which explores physics-aware machine learning and neural-ordinary-differential-equations (ODE-Net) to discover a dynamic equivalence of external power grids while preserving its dynamic behaviors after disturbances. The contributions are threefold: 1) an ODE-Net-enabled NeuDyE formulation to enable a continuous-time, data-driven dynamic equivalence of power systems; 2) a physics-informed NeuDyE learning method (PI-NeuDyE) to actively control the closed-loop accuracy of NeuDyE without an additional verification module; 3) a physics-guided NeuDyE (PG-NeuDyE) to enhance the method's applicability even in the absence of analytical physics models. Extensive case studies in the NPCC system validate the efficacy of NeuDyE, and, in particular, its capability under various contingencies.

Original language	English
Pages (from-to)	2341-2344
Number of pages	4
Journal	IEEE Transactions on Power Systems
Volume	39
Issue number	1
DOIs	https://doi.org/10.1109/TPWRS.2023.3328162
State	Published - Jan 1 2024

Keywords

Dynamic equivalence
ODE-Net
model order reduction
physics-informed machine learning

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10.1109/TPWRS.2023.3328162

Cite this

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title = "Physics-Aware Neural Dynamic Equivalence of Power Systems",

abstract = "This letter devises Neural Dynamic Equivalence (NeuDyE), which explores physics-aware machine learning and neural-ordinary-differential-equations (ODE-Net) to discover a dynamic equivalence of external power grids while preserving its dynamic behaviors after disturbances. The contributions are threefold: 1) an ODE-Net-enabled NeuDyE formulation to enable a continuous-time, data-driven dynamic equivalence of power systems; 2) a physics-informed NeuDyE learning method (PI-NeuDyE) to actively control the closed-loop accuracy of NeuDyE without an additional verification module; 3) a physics-guided NeuDyE (PG-NeuDyE) to enhance the method's applicability even in the absence of analytical physics models. Extensive case studies in the NPCC system validate the efficacy of NeuDyE, and, in particular, its capability under various contingencies.",

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author = "Qing Shen and Yifan Zhou and Qiang Zhang and Slava Maslennikov and Xiaochuan Luo and Peng Zhang",

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AU - Zhou, Yifan

AU - Zhang, Qiang

AU - Maslennikov, Slava

AU - Luo, Xiaochuan

AU - Zhang, Peng

PY - 2024/1/1

Y1 - 2024/1/1

N2 - This letter devises Neural Dynamic Equivalence (NeuDyE), which explores physics-aware machine learning and neural-ordinary-differential-equations (ODE-Net) to discover a dynamic equivalence of external power grids while preserving its dynamic behaviors after disturbances. The contributions are threefold: 1) an ODE-Net-enabled NeuDyE formulation to enable a continuous-time, data-driven dynamic equivalence of power systems; 2) a physics-informed NeuDyE learning method (PI-NeuDyE) to actively control the closed-loop accuracy of NeuDyE without an additional verification module; 3) a physics-guided NeuDyE (PG-NeuDyE) to enhance the method's applicability even in the absence of analytical physics models. Extensive case studies in the NPCC system validate the efficacy of NeuDyE, and, in particular, its capability under various contingencies.

AB - This letter devises Neural Dynamic Equivalence (NeuDyE), which explores physics-aware machine learning and neural-ordinary-differential-equations (ODE-Net) to discover a dynamic equivalence of external power grids while preserving its dynamic behaviors after disturbances. The contributions are threefold: 1) an ODE-Net-enabled NeuDyE formulation to enable a continuous-time, data-driven dynamic equivalence of power systems; 2) a physics-informed NeuDyE learning method (PI-NeuDyE) to actively control the closed-loop accuracy of NeuDyE without an additional verification module; 3) a physics-guided NeuDyE (PG-NeuDyE) to enhance the method's applicability even in the absence of analytical physics models. Extensive case studies in the NPCC system validate the efficacy of NeuDyE, and, in particular, its capability under various contingencies.

KW - Dynamic equivalence

KW - ODE-Net

KW - model order reduction

KW - physics-informed machine learning

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JO - IEEE Transactions on Power Systems

JF - IEEE Transactions on Power Systems

IS - 1

ER -

Physics-Aware Neural Dynamic Equivalence of Power Systems

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Keywords

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