Dual-branch Spatial-Temporal Self-supervised Representation for Enhanced Road Network Learning

Authors

  • Qinghong Guo State Key Laboratory of Blockchain and Data Security, Zhejiang University
  • Yu Wang State Key Laboratory of Blockchain and Data Security, Zhejiang University
  • Ji Cao State Key Laboratory of Blockchain and Data Security, Zhejiang University
  • Tongya Zheng State Key Laboratory of Blockchain and Data Security, Zhejiang University Zhejiang Provincial Engineering Research Center for Real-Time Smart Tech in Urban Security Governance, School of Computer and Computing Science, Hangzhou City University Hangzhou High-Tech Zone (Binjiang) Institute of Blockchain and Data Security
  • Junshu Dai State Key Laboratory of Blockchain and Data Security, Zhejiang University
  • Bingde Hu State Key Laboratory of Blockchain and Data Security, Zhejiang University Bangsun Technology
  • Shunyu Liu Nanyang Technological University
  • Canghong Jin Zhejiang Provincial Engineering Research Center for Real-Time Smart Tech in Urban Security Governance, School of Computer and Computing Science, Hangzhou City University

DOI:

https://doi.org/10.1609/aaai.v40i45.41194

Abstract

Road network representation learning (RNRL) has attracted increasing attention from both researchers and practitioners as various spatiotemporal tasks are emerging. Recent advanced methods leverage Graph Neural Networks (GNNs) and contrastive learning to characterize the spatial structure of road segments in a self-supervised paradigm. However, spatial heterogeneity and temporal dynamics of road networks raise severe challenges to the neighborhood smoothing mechanism of self-supervised GNNs. To address these issues, we propose a Dual-branch Spatial-Temporal self-supervised representation framework for enhanced road representations, termed as DST. On one hand, DST designs a mix-hop transition matrix for graph convolution to incorporate dynamic relations of roads from trajectories. Besides, DST contrasts road representations of the vanilla road network against that of hypergraphs in a spatial self-supervised way. The hypergraph is newly built based on three types of hyperedges to capture long-range relations. On the other hand, DST performs next token prediction as the temporal self-supervised task on the sequences of traffic dynamics based on a causal Transformer, which is further regularized by differentiating traffic modes of weekdays from those of weekends. Extensive experiments against state-of-the-art methods verify the superiority of our proposed framework. Moreover, the comprehensive spatiotemporal modeling facilitates DST to excel in zero-shot learning scenarios.

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Published

2026-03-14

How to Cite

Guo, Q., Wang, Y., Cao, J., Zheng, T., Dai, J., Hu, B., … Jin, C. (2026). Dual-branch Spatial-Temporal Self-supervised Representation for Enhanced Road Network Learning. Proceedings of the AAAI Conference on Artificial Intelligence, 40(45), 38524–38532. https://doi.org/10.1609/aaai.v40i45.41194

Issue

Section

AAAI Special Track on AI for Social Impact I