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Auteurs principaux: Fan, Hang, Li, Mingxuan, Cui, Jingshi, Zhang, Zuhan, Run, Wencai, Liu, Dunnan
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2506.03728
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author Fan, Hang
Li, Mingxuan
Cui, Jingshi
Zhang, Zuhan
Run, Wencai
Liu, Dunnan
author_facet Fan, Hang
Li, Mingxuan
Cui, Jingshi
Zhang, Zuhan
Run, Wencai
Liu, Dunnan
contents The rapid growth of EVs and the subsequent increase in charging demand pose significant challenges for load grid scheduling and the operation of EV charging stations. Effectively harnessing the spatiotemporal correlations among EV charging stations to improve forecasting accuracy is complex. To tackle these challenges, we propose EV-LLM for EV charging loads based on LLMs in this paper. EV-LLM integrates the strengths of Graph Convolutional Networks (GCNs) in spatiotemporal feature extraction with the generalization capabilities of fine-tuned generative LLMs. Also, EV-LLM enables effective data mining and feature extraction across multimodal and multidimensional datasets, incorporating historical charging data, weather information, and relevant textual descriptions to enhance forecasting accuracy for multiple charging stations. We validate the effectiveness of EV-LLM by using charging data from 10 stations in California, demonstrating its superiority over the other traditional deep learning methods and potential to optimize load grid scheduling and support vehicle-to-grid interactions.
format Preprint
id arxiv_https___arxiv_org_abs_2506_03728
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Spatiotemporal Prediction of Electric Vehicle Charging Load Based on Large Language Models
Fan, Hang
Li, Mingxuan
Cui, Jingshi
Zhang, Zuhan
Run, Wencai
Liu, Dunnan
Signal Processing
The rapid growth of EVs and the subsequent increase in charging demand pose significant challenges for load grid scheduling and the operation of EV charging stations. Effectively harnessing the spatiotemporal correlations among EV charging stations to improve forecasting accuracy is complex. To tackle these challenges, we propose EV-LLM for EV charging loads based on LLMs in this paper. EV-LLM integrates the strengths of Graph Convolutional Networks (GCNs) in spatiotemporal feature extraction with the generalization capabilities of fine-tuned generative LLMs. Also, EV-LLM enables effective data mining and feature extraction across multimodal and multidimensional datasets, incorporating historical charging data, weather information, and relevant textual descriptions to enhance forecasting accuracy for multiple charging stations. We validate the effectiveness of EV-LLM by using charging data from 10 stations in California, demonstrating its superiority over the other traditional deep learning methods and potential to optimize load grid scheduling and support vehicle-to-grid interactions.
title Spatiotemporal Prediction of Electric Vehicle Charging Load Based on Large Language Models
topic Signal Processing
url https://arxiv.org/abs/2506.03728