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Improving spatial allocation for energy system coupling with graph neural networks

Mu, Xuanhao ORCID iD icon 1; Geiges, Jakob ORCID iD icon 1; Liu, Nan ORCID iD icon 1; Schlachter, Thorsten ORCID iD icon 1; Hagenmeyer, Veit ORCID iD icon 1
1 Institut für Automation und angewandte Informatik (IAI), Karlsruher Institut für Technologie (KIT)

Abstract:

In energy system analysis, coupling models with mismatched spatial resolutions is a significant challenge. A common solution is assigning weights to high-resolution geographic units for aggregation, but traditional models are limited by using only a single geospatial attribute. This paper presents an innovative method employing a self-supervised Heterogeneous Graph Neural Network to address this issue. This method models high-resolution geographic units as graph nodes, integrating various geographical features to generate physically meaningful weights for each grid point. These weights enhance the conventional Voronoi-based allocation method, allowing it to go beyond simply geographic proximity by incorporating essential geographic information. In addition, the self-supervised learning paradigm overcomes the lack of accurate ground-truth data. Experimental results demonstrate that applying weights generated by this method to cluster-based Voronoi Diagrams significantly enhances scalability, accuracy, and physical plausibility, while increasing precision compared to traditional methods. Code is available at https://github.com/KIT-IAI/AllocateGNN


Verlagsausgabe §
DOI: 10.5445/IR/1000195253
Veröffentlicht am 14.07.2026
Originalveröffentlichung
DOI: 10.1016/j.epsr.2026.113519
Cover der Publikation
Zugehörige Institution(en) am KIT Institut für Automation und angewandte Informatik (IAI)
Publikationstyp Zeitschriftenaufsatz
Publikationsmonat/-jahr 01.2027
Sprache Englisch
Identifikator ISSN: 0378-7796
KITopen-ID: 1000195253
HGF-Programm 37.12.02 (POF IV, LK 01) Design,Operation & Digitalization of the Future Energy Grids
Erschienen in Electric Power Systems Research
Verlag Elsevier
Band 262
Seiten Art.Nr: 113519
Vorab online veröffentlicht am 30.06.2026
Schlagwörter Deep learning; Energy system coupling; Granularity gap; Graph neural network; Spatial resolution
Nachgewiesen in Scopus
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