A graph neural network enhanced decision transformer for efficient optimization in dynamic smart charging environments
Stavros Orfanoudakis (TU Delft - Intelligent Electrical Power Grids)
Nanda Kishor Panda (TU Delft - Intelligent Electrical Power Grids)
Peter Palensky (TU Delft - Electrical Sustainable Energy)
Pedro P. Vergara (TU Delft - Intelligent Electrical Power Grids)
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Abstract
Electric-vehicle smart charging requires quick decision-making under uncertainty while enforcing strict electricity grid and user requirements. Mathematical optimization becomes too slow at scale, while online reinforcement learning struggles with sparse rewards and safety. This paper proposes GNN-DT, a topology-aware Decision Transformer that combines graph neural network embeddings with sequence modeling to learn charging policies from offline trajectories. The method operates over variable numbers of vehicles and chargers without retraining. Evaluated on realistic smart charging scenarios, GNN-DT achieves near-optimal performance, reaching rewards within 5 percent of an oracle solver while using up to 10× fewer training trajectories than baseline methods. It consistently outperforms online and offline reinforcement learning approaches and generalizes to unseen fleet sizes and network topologies. Inference runs in milliseconds, making the approach suitable for real-time deployment in large-scale charging systems.
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