Knowledge Probing for Graph Representation Learning
Zhao, Mingyu, Huang, Xingyu, Lyu, Ziyu, Wang, Yanlin, Cui, Lixin, Bai, Lu
–arXiv.org Artificial Intelligence
Graph learning methods have been extensively applied in diverse application areas. However, what kind of inherent graph properties e.g. graph proximity, graph structural information has been encoded into graph representation learning for downstream tasks is still under-explored. In this paper, we propose a novel graph probing framework (GraphProbe) to investigate and interpret whether the family of graph learning methods has encoded different levels of knowledge in graph representation learning. Based on the intrinsic properties of graphs, we design three probes to systematically investigate the graph representation learning process from different perspectives, respectively the node-wise level, the path-wise level, and the structural level. We construct a thorough evaluation benchmark with nine representative graph learning methods from random walk based approaches, basic graph neural networks and self-supervised graph methods, and probe them on six benchmark datasets for node classification, link prediction and graph classification. The experimental evaluation verify that GraphProbe can estimate the capability of graph representation learning. Remaking results have been concluded: GCN and WeightedGCN methods are relatively versatile methods achieving better results with respect to different tasks.
arXiv.org Artificial Intelligence
Aug-7-2024
- Country:
- Oceania > Australia
- North America > United States
- Texas > Travis County
- Austin (0.04)
- New York > New York County
- New York City (0.05)
- Minnesota > Hennepin County
- Minneapolis (0.14)
- Louisiana > Orleans Parish
- New Orleans (0.04)
- Texas > Travis County
- Asia > China
- Beijing > Beijing (0.04)
- Hubei Province > Wuhan (0.04)
- Hong Kong (0.04)
- Guangdong Province
- Genre:
- Research Report (0.82)
- Industry:
- Technology: