Learning graph-level representation from local-structural distribution with Graph Neural Networks
作者:
Highlights:
•
摘要
Graph Neural Networks has been proved to be successful in learning the latent vector representation for local structures. While applying this technique to some real-world tasks, such as property prediction for molecules, a graph-level representation generator should be required to integrate all these local-structural embeddings. Limited by varying graph scale and the absence of node order, existing graph-level representation generation approaches usually adopt rough ways, e.g., compressing all local-structural embeddings into a single vector, which cannot simultaneously retain both the local- and global-structural information in graph-level representations. To address this problem, this paper introduces a novel and more powerful approach to learn graph-level representation from local-structural distribution. Firstly, our approach employs a batch strategy to discretize the embeddings of local structures by their structural semantics, which can provide interactive information to approximately align the local-structural embeddings for varying graphs. According to Wasserstein metric, the aligned structural information is beneficial to capture the similarity among graphs. Then, our approach further integrates these aligned local-structural embeddings to construct a resolution-controllable structural histogram as the graph-level representation. Without over-compression, more local-structural information can be preserved. The experimental results show that our approach substantially outperformed the baselines on a range of real-world datasets in both graph classification and regression tasks.
论文关键词:Graph-level representation learning,Local-structural distribution,Graph Neural Networks
论文评审过程:Received 31 January 2021, Revised 4 August 2021, Accepted 10 August 2021, Available online 12 August 2021, Version of Record 26 August 2021.
论文官网地址:https://doi.org/10.1016/j.knosys.2021.107383