English

Large Language Model Powered Automated Modeling and Optimization of Active Distribution Network Dispatch Problems

Artificial Intelligence 2025-07-30 v1 Machine Learning Systems and Control Systems and Control

Abstract

The increasing penetration of distributed energy resources into active distribution networks (ADNs) has made effective ADN dispatch imperative. However, the numerous newly-integrated ADN operators, such as distribution system aggregators, virtual power plant managers, and end prosumers, often lack specialized expertise in power system operation, modeling, optimization, and programming. This knowledge gap renders reliance on human experts both costly and time-intensive. To address this challenge and enable intelligent, flexible ADN dispatch, this paper proposes a large language model (LLM) powered automated modeling and optimization approach. First, the ADN dispatch problems are decomposed into sequential stages, and a multi-LLM coordination architecture is designed. This framework comprises an Information Extractor, a Problem Formulator, and a Code Programmer, tasked with information retrieval, optimization problem formulation, and code implementation, respectively. Afterwards, tailored refinement techniques are developed for each LLM agent, greatly improving the accuracy and reliability of generated content. The proposed approach features a user-centric interface that enables ADN operators to derive dispatch strategies via simple natural language queries, eliminating technical barriers and increasing efficiency. Comprehensive comparisons and end-to-end demonstrations on various test cases validate the effectiveness of the proposed architecture and methods.

Keywords

Cite

@article{arxiv.2507.21162,
  title  = {Large Language Model Powered Automated Modeling and Optimization of Active Distribution Network Dispatch Problems},
  author = {Xu Yang and Chenhui Lin and Yue Yang and Qi Wang and Haotian Liu and Haizhou Hua and Wenchuan Wu},
  journal= {arXiv preprint arXiv:2507.21162},
  year   = {2025}
}
R2 v1 2026-07-01T04:22:44.270Z