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Main Authors: Gao, Xin, Li, Xueyuan, Liu, Hao, Li, Ao, Ma, Zhaoyang, Li, Zirui
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2408.07578
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author Gao, Xin
Li, Xueyuan
Liu, Hao
Li, Ao
Ma, Zhaoyang
Li, Zirui
author_facet Gao, Xin
Li, Xueyuan
Liu, Hao
Li, Ao
Ma, Zhaoyang
Li, Zirui
contents Platooning technology is renowned for its precise vehicle control, traffic flow optimization, and energy efficiency enhancement. However, in large-scale mixed platoons, vehicle heterogeneity and unpredictable traffic conditions lead to virtual bottlenecks. These bottlenecks result in reduced traffic throughput and increased energy consumption within the platoon. To address these challenges, we introduce a decision-making strategy based on nested graph reinforcement learning. This strategy improves collaborative decision-making, ensuring energy efficiency and alleviating congestion. We propose a theory of nested traffic graph representation that maps dynamic interactions between vehicles and platoons in non-Euclidean spaces. By incorporating spatio-temporal weighted graph into a multi-head attention mechanism, we further enhance the model's capacity to process both local and global data. Additionally, we have developed a nested graph reinforcement learning framework to enhance the self-iterative learning capabilities of platooning. Using the I-24 dataset, we designed and conducted comparative algorithm experiments, generalizability testing, and permeability ablation experiments, thereby validating the proposed strategy's effectiveness. Compared to the baseline, our strategy increases throughput by 10% and decreases energy use by 9%. Specifically, increasing the penetration rate of CAVs significantly enhances traffic throughput, though it also increases energy consumption.
format Preprint
id arxiv_https___arxiv_org_abs_2408_07578
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle A Nested Graph Reinforcement Learning-based Decision-making Strategy for Eco-platooning
Gao, Xin
Li, Xueyuan
Liu, Hao
Li, Ao
Ma, Zhaoyang
Li, Zirui
Multiagent Systems
Machine Learning
Platooning technology is renowned for its precise vehicle control, traffic flow optimization, and energy efficiency enhancement. However, in large-scale mixed platoons, vehicle heterogeneity and unpredictable traffic conditions lead to virtual bottlenecks. These bottlenecks result in reduced traffic throughput and increased energy consumption within the platoon. To address these challenges, we introduce a decision-making strategy based on nested graph reinforcement learning. This strategy improves collaborative decision-making, ensuring energy efficiency and alleviating congestion. We propose a theory of nested traffic graph representation that maps dynamic interactions between vehicles and platoons in non-Euclidean spaces. By incorporating spatio-temporal weighted graph into a multi-head attention mechanism, we further enhance the model's capacity to process both local and global data. Additionally, we have developed a nested graph reinforcement learning framework to enhance the self-iterative learning capabilities of platooning. Using the I-24 dataset, we designed and conducted comparative algorithm experiments, generalizability testing, and permeability ablation experiments, thereby validating the proposed strategy's effectiveness. Compared to the baseline, our strategy increases throughput by 10% and decreases energy use by 9%. Specifically, increasing the penetration rate of CAVs significantly enhances traffic throughput, though it also increases energy consumption.
title A Nested Graph Reinforcement Learning-based Decision-making Strategy for Eco-platooning
topic Multiagent Systems
Machine Learning
url https://arxiv.org/abs/2408.07578