An Intelligent End-to-End Neural Architecture Search Framework for Electricity Forecasting Model Development

TL;DR

This paper introduces an automated neural architecture search framework for electricity forecasting that enhances model accuracy and adaptability, addressing limitations of manual design and previous NAS methods in power system applications.

Contribution

The paper presents a novel IAAS framework combining network transformation, reinforcement learning, and heuristic screening for improved electricity forecasting models.

Findings

Outperforms existing models in accuracy and stability

Demonstrates effectiveness across multiple datasets

Highlights importance of key framework components

Abstract

Recent years have witnessed exponential growth in developing deep learning (DL) models for time-series electricity forecasting in power systems. However, most of the proposed models are designed based on the designers' inherent knowledge and experience without elaborating on the suitability of the proposed neural architectures. Moreover, these models cannot be self-adjusted to dynamically changed data patterns due to the inflexible design of their structures. Although several recent studies have considered the application of the neural architecture search (NAS) technique for obtaining a network with an optimized structure in the electricity forecasting sector, their training process is computationally expensive and their search strategies are not flexible, indicating that the NAS application in this area is still at an infancy stage. In this study, we propose an intelligent automated architecture search (IAAS) framework for the development of time-series electricity forecasting models. The proposed framework contains three primary components, i.e., network function-preserving transformation operation, reinforcement learning (RL)-based network transformation control, and heuristic network screening, which aim to improve the search quality of a network structure. After conducting comprehensive experiments on two publicly-available electricity load datasets and two wind power datasets, we demonstrate that the proposed IAAS framework significantly outperforms the ten existing models or methods in terms of forecasting accuracy and stability. Finally, we perform an ablation experiment to showcase the importance of critical components in the proposed IAAS framework in improving forecasting accuracy.