English

An Explainable Framework for Machine learning-Based Reactive Power Optimization of Distribution Network

Systems and Control 2023-11-08 v1 Machine Learning Systems and Control

Abstract

To reduce the heavy computational burden of reactive power optimization of distribution networks, machine learning models are receiving increasing attention. However, most machine learning models (e.g., neural networks) are usually considered as black boxes, making it challenging for power system operators to identify and comprehend potential biases or errors in the decision-making process of machine learning models. To address this issue, an explainable machine-learning framework is proposed to optimize the reactive power in distribution networks. Firstly, a Shapley additive explanation framework is presented to measure the contribution of each input feature to the solution of reactive power optimizations generated from machine learning models. Secondly, a model-agnostic approximation method is developed to estimate Shapley values, so as to avoid the heavy computational burden associated with direct calculations of Shapley values. The simulation results show that the proposed explainable framework can accurately explain the solution of the machine learning model-based reactive power optimization by using visual analytics, from both global and instance perspectives. Moreover, the proposed explainable framework is model-agnostic, and thus applicable to various models (e.g., neural networks).

Keywords

Cite

@article{arxiv.2311.03863,
  title  = {An Explainable Framework for Machine learning-Based Reactive Power Optimization of Distribution Network},
  author = {Wenlong Liao and Benjamin Schäfer and Dalin Qin and Gonghao Zhang and Zhixian Wang and Zhe Yang},
  journal= {arXiv preprint arXiv:2311.03863},
  year   = {2023}
}

Comments

It was submitted to the 23rd Power Systems Computation Conference (PSCC 2024) on Sept.2023

R2 v1 2026-06-28T13:13:50.911Z