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Hyperbolic Geometric Graph Representation Learning for Hierarchy-imbalance Node Classification

Machine Learning 2023-04-12 v1 Social and Information Networks

Abstract

Learning unbiased node representations for imbalanced samples in the graph has become a more remarkable and important topic. For the graph, a significant challenge is that the topological properties of the nodes (e.g., locations, roles) are unbalanced (topology-imbalance), other than the number of training labeled nodes (quantity-imbalance). Existing studies on topology-imbalance focus on the location or the local neighborhood structure of nodes, ignoring the global underlying hierarchical properties of the graph, i.e., hierarchy. In the real-world scenario, the hierarchical structure of graph data reveals important topological properties of graphs and is relevant to a wide range of applications. We find that training labeled nodes with different hierarchical properties have a significant impact on the node classification tasks and confirm it in our experiments. It is well known that hyperbolic geometry has a unique advantage in representing the hierarchical structure of graphs. Therefore, we attempt to explore the hierarchy-imbalance issue for node classification of graph neural networks with a novelty perspective of hyperbolic geometry, including its characteristics and causes. Then, we propose a novel hyperbolic geometric hierarchy-imbalance learning framework, named HyperIMBA, to alleviate the hierarchy-imbalance issue caused by uneven hierarchy-levels and cross-hierarchy connectivity patterns of labeled nodes.Extensive experimental results demonstrate the superior effectiveness of HyperIMBA for hierarchy-imbalance node classification tasks.

Keywords

Cite

@article{arxiv.2304.05059,
  title  = {Hyperbolic Geometric Graph Representation Learning for Hierarchy-imbalance Node Classification},
  author = {Xingcheng Fu and Yuecen Wei and Qingyun Sun and Haonan Yuan and Jia Wu and Hao Peng and Jianxin Li},
  journal= {arXiv preprint arXiv:2304.05059},
  year   = {2023}
}

Comments

Accepted by Web Conference (WWW) 2023

R2 v1 2026-06-28T09:59:07.954Z