Litcius/Paper detail

Sparse dynamic graph learning for district heat load forecasting

Yaohui Huang, Yuan Zhao, Zhijin Wang, Xiufeng Liu, Yonggang Fu

2024Applied Energy14 citationsDOIOpen Access PDF

Abstract

Accurate heat load forecasting is crucial for the efficient operation and management of district heating systems. This study introduces a novel Sparse Dynamic Graph Neural Network (SDGNN) framework designed to address the complexities of forecasting heat load in district heating networks. The proposed model represents the district heating network as a dynamic graph, with nodes corresponding to consumers or heat sources and edges denoting temporal dependencies. The SDGNN framework comprises three key components: (1) a sparse graph learning module that identifies the most relevant nodes and edges, (2) a spatio-temporal memory enhancement module that captures both short-term and long-term dependencies, and (3) a temporal fusion module that integrates node representations into a comprehensive global forecast. Evaluated on a real-world district heating dataset from Denmark, the SDGNN model demonstrates superior accuracy and efficiency compared to existing methods. The results indicate that the SDGNN framework effectively captures intricate spatio-temporal patterns in historical heat load data, achieving up to 5.7% improvement in RMSE, 7.4% in MAE, and 5.7% in CVRMSE over baseline models. Additionally, incorporating meteorological factors into the model further enhances its predictive performance. These findings suggest that the SDGNN framework is a robust and scalable solution for district heat load forecasting, with potential applications in other domains involving spatio-temporal graph data. • A novel graph-based learning framework for heat load forecasting. • Integrates graph neural networks to capture spatio-temporal dependencies. • Achieves state-of-the-art results on real-world district heating data. • Applicable to various spatio-temporal prediction tasks.

Topics & Concepts

GraphComputer scienceMachine learningArtificial intelligenceTheoretical computer scienceEnergy Load and Power ForecastingIntegrated Energy Systems OptimizationAtmospheric and Environmental Gas Dynamics