Optimisation of Spectral Wavelets for Persistence-based Graph Classification
Abstract
A graph's spectral wavelet signature determines a filtration, and consequently an associated set of extended persistence diagrams. We propose a framework that optimises the choice of wavelet for a dataset of graphs, such that their associated persistence diagrams capture features of the graphs that are best suited to a given data science problem. Since the spectral wavelet signature of a graph is derived from its Laplacian, our framework encodes geometric properties of graphs in their associated persistence diagrams and can be applied to graphs without a priori node attributes. We apply our framework to graph classification problems and obtain performances competitive with other persistence-based architectures. To provide the underlying theoretical foundations, we extend the differentiability result for ordinary persistent homology to extended persistent homology.
Keywords
Cite
@article{arxiv.2101.05201,
title = {Optimisation of Spectral Wavelets for Persistence-based Graph Classification},
author = {Ka Man Yim and Jacob Leygonie},
journal= {arXiv preprint arXiv:2101.05201},
year = {2023}
}