NN-induced Physical Information Dynamic Library for Transient Modeling of Large-Scale Wind Farm

Hongyi Wang; Pingyang Sun; Georgios Konstantinou; Zhe Chen

NN-induced Physical Information Dynamic Library for Transient Modeling of Large-Scale Wind Farm

Hongyi Wang, Pingyang Sun, Georgios Konstantinou, Zhe Chen

Research output: Contribution to journal › Conference article in Journal › Research › peer-review

Abstract

The complexity of transient characteristics in large-scale wind farms (WF) hinders the application of machine learning algorithms. This paper proposes a neural network-based learning method to provide physical information cues for the learning framework of transient characteristics in large-scale WF induced by physical information. The complexity of the physical information repository is simplified through an iterative algorithm. The dynamic library obtained based on neural networks can induce the machine learning framework to rapidly learn the transient characteristics of large-scale WF. Moreover, there is no need for excessive mechanistic analysis and speculation regarding the transient behavior of WF. The effectiveness of the proposed method is verified in the simulation model of a WF.

Original language	English
Journal	The 10th International Conference on Automation, Robotics, and Applications (ICARA 2024)
Number of pages	5
Publication status	Submitted - 2024

Cite this

@inproceedings{0d87390750604200856084f9d43d3cfa,

title = "NN-induced Physical Information Dynamic Library for Transient Modeling of Large-Scale Wind Farm",

abstract = "The complexity of transient characteristics in large-scale wind farms (WF) hinders the application of machine learning algorithms. This paper proposes a neural network-based learning method to provide physical information cues for the learning framework of transient characteristics in large-scale WF induced by physical information. The complexity of the physical information repository is simplified through an iterative algorithm. The dynamic library obtained based on neural networks can induce the machine learning framework to rapidly learn the transient characteristics of large-scale WF. Moreover, there is no need for excessive mechanistic analysis and speculation regarding the transient behavior of WF. The effectiveness of the proposed method is verified in the simulation model of a WF.",

author = "Hongyi Wang and Pingyang Sun and Georgios Konstantinou and Zhe Chen",

year = "2024",

language = "English",

journal = "The 10th International Conference on Automation, Robotics, and Applications (ICARA 2024)",

}

TY - GEN

T1 - NN-induced Physical Information Dynamic Library for Transient Modeling of Large-Scale Wind Farm

AU - Wang, Hongyi

AU - Sun, Pingyang

AU - Konstantinou, Georgios

AU - Chen, Zhe

PY - 2024

Y1 - 2024

N2 - The complexity of transient characteristics in large-scale wind farms (WF) hinders the application of machine learning algorithms. This paper proposes a neural network-based learning method to provide physical information cues for the learning framework of transient characteristics in large-scale WF induced by physical information. The complexity of the physical information repository is simplified through an iterative algorithm. The dynamic library obtained based on neural networks can induce the machine learning framework to rapidly learn the transient characteristics of large-scale WF. Moreover, there is no need for excessive mechanistic analysis and speculation regarding the transient behavior of WF. The effectiveness of the proposed method is verified in the simulation model of a WF.

AB - The complexity of transient characteristics in large-scale wind farms (WF) hinders the application of machine learning algorithms. This paper proposes a neural network-based learning method to provide physical information cues for the learning framework of transient characteristics in large-scale WF induced by physical information. The complexity of the physical information repository is simplified through an iterative algorithm. The dynamic library obtained based on neural networks can induce the machine learning framework to rapidly learn the transient characteristics of large-scale WF. Moreover, there is no need for excessive mechanistic analysis and speculation regarding the transient behavior of WF. The effectiveness of the proposed method is verified in the simulation model of a WF.

M3 - Conference article in Journal

JO - The 10th International Conference on Automation, Robotics, and Applications (ICARA 2024)

JF - The 10th International Conference on Automation, Robotics, and Applications (ICARA 2024)

ER -

NN-induced Physical Information Dynamic Library for Transient Modeling of Large-Scale Wind Farm

Abstract

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