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Autori principali: Lin, Ding, Guo, Han, Wang, Jianhui, Yue, Meng, Zhao, Tianqiao
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2503.06879
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author Lin, Ding
Guo, Han
Wang, Jianhui
Yue, Meng
Zhao, Tianqiao
author_facet Lin, Ding
Guo, Han
Wang, Jianhui
Yue, Meng
Zhao, Tianqiao
contents With the increasing penetration of renewable energy sources, growing demand variability, and evolving grid control strategies, accurate and efficient load modeling has become a critical yet challenging task. Traditional methods, such as fixed-form parametric models and data-driven approaches, often struggle to balance accuracy, computational efficiency, and interpretability. This paper introduces a novel symbolic regression algorithm based on the Actor-Critic reinforcement learning framework, specifically tailored for dynamic load modeling. The algorithm employs a trainable expression tree with controlled depth and a predefined set of operators to generate compact and interpretable mathematical expressions. The Actor network probabilistically selects operators for the symbolic expression, while the Critic evaluates the resulting expression tree through a loss function. To further enhance performance, a candidate pool mechanism is implemented to store high-performing expressions, which are subsequently fine-tuned using gradient descent. By focusing on simplicity and precision, the proposed method significantly reduces computational complexity while preserving interpretability. Experimental results validate its superior performance compared to existing benchmarks, which offers a robust and scalable solution for dynamic load modeling and system analysis in modern power systems.
format Preprint
id arxiv_https___arxiv_org_abs_2503_06879
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Reinforcement Learning Based Symbolic Regression for Load Modeling
Lin, Ding
Guo, Han
Wang, Jianhui
Yue, Meng
Zhao, Tianqiao
Systems and Control
With the increasing penetration of renewable energy sources, growing demand variability, and evolving grid control strategies, accurate and efficient load modeling has become a critical yet challenging task. Traditional methods, such as fixed-form parametric models and data-driven approaches, often struggle to balance accuracy, computational efficiency, and interpretability. This paper introduces a novel symbolic regression algorithm based on the Actor-Critic reinforcement learning framework, specifically tailored for dynamic load modeling. The algorithm employs a trainable expression tree with controlled depth and a predefined set of operators to generate compact and interpretable mathematical expressions. The Actor network probabilistically selects operators for the symbolic expression, while the Critic evaluates the resulting expression tree through a loss function. To further enhance performance, a candidate pool mechanism is implemented to store high-performing expressions, which are subsequently fine-tuned using gradient descent. By focusing on simplicity and precision, the proposed method significantly reduces computational complexity while preserving interpretability. Experimental results validate its superior performance compared to existing benchmarks, which offers a robust and scalable solution for dynamic load modeling and system analysis in modern power systems.
title Reinforcement Learning Based Symbolic Regression for Load Modeling
topic Systems and Control
url https://arxiv.org/abs/2503.06879