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Bibliographic Details
Main Authors: Lawrence, Zach, Yao, Jessica, Qin, Chris
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2512.00728
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author Lawrence, Zach
Yao, Jessica
Qin, Chris
author_facet Lawrence, Zach
Yao, Jessica
Qin, Chris
contents Wind farms with integrated energy storage, or hybrid wind farms, are able to store energy and dispatch it to the grid following an operational strategy. For individual wind farms with integrated energy storage capacity, data-driven dispatch strategies using localized grid demand and market conditions as input parameters stand to maximize wind energy value. Synthetic power generation data modeled on atmospheric conditions provide another avenue for improving the robustness of data-driven dispatch strategies. To these ends, the present work develops two deep learning frameworks: COVE-NN, an LSTM-based dispatch strategy tailored to individual wind farms, which reduced annual COVE by 32.3% over 43 years of simulated operations in a case study at the Pyron site; and a power generation modeling framework that reduced RMSE by 9.5% and improved power curve similarity by 18.9% when validated on the Palouse wind farm. Together, these models pave the way for more robust, data-driven dispatch strategies and potential extensions to other renewable energy systems.
format Preprint
id arxiv_https___arxiv_org_abs_2512_00728
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Deep Learning for Modeling and Dispatching Hybrid Wind Farm Power Generation
Lawrence, Zach
Yao, Jessica
Qin, Chris
Machine Learning
Artificial Intelligence
Wind farms with integrated energy storage, or hybrid wind farms, are able to store energy and dispatch it to the grid following an operational strategy. For individual wind farms with integrated energy storage capacity, data-driven dispatch strategies using localized grid demand and market conditions as input parameters stand to maximize wind energy value. Synthetic power generation data modeled on atmospheric conditions provide another avenue for improving the robustness of data-driven dispatch strategies. To these ends, the present work develops two deep learning frameworks: COVE-NN, an LSTM-based dispatch strategy tailored to individual wind farms, which reduced annual COVE by 32.3% over 43 years of simulated operations in a case study at the Pyron site; and a power generation modeling framework that reduced RMSE by 9.5% and improved power curve similarity by 18.9% when validated on the Palouse wind farm. Together, these models pave the way for more robust, data-driven dispatch strategies and potential extensions to other renewable energy systems.
title Deep Learning for Modeling and Dispatching Hybrid Wind Farm Power Generation
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2512.00728