English

Limitless stability for Graph Convolutional Networks

Machine Learning 2023-10-03 v3 Functional Analysis

Abstract

This work establishes rigorous, novel and widely applicable stability guarantees and transferability bounds for graph convolutional networks -- without reference to any underlying limit object or statistical distribution. Crucially, utilized graph-shift operators (GSOs) are not necessarily assumed to be normal, allowing for the treatment of networks on both undirected- and for the first time also directed graphs. Stability to node-level perturbations is related to an 'adequate (spectral) covering' property of the filters in each layer. Stability to edge-level perturbations is related to Lipschitz constants and newly introduced semi-norms of filters. Results on stability to topological perturbations are obtained through recently developed mathematical-physics based tools. As an important and novel example, it is showcased that graph convolutional networks are stable under graph-coarse-graining procedures (replacing strongly-connected sub-graphs by single nodes) precisely if the GSO is the graph Laplacian and filters are regular at infinity. These new theoretical results are supported by corresponding numerical investigations.

Keywords

Cite

@article{arxiv.2301.11443,
  title  = {Limitless stability for Graph Convolutional Networks},
  author = {Christian Koke},
  journal= {arXiv preprint arXiv:2301.11443},
  year   = {2023}
}
R2 v1 2026-06-28T08:22:30.592Z