Graph convolutional networks (GCNs) are \emph{discriminative models} that directly model the class posterior p(y∣x) for semi-supervised classification of graph data. While being effective, as a representation learning approach, the node representations extracted from a GCN often miss useful information for effective clustering, because the objectives are different. In this work, we design normalizing flows that replace GCN layers, leading to a \emph{generative model} that models both the class conditional likelihood p(x∣y) and the class prior p(y). The resulting neural network, GC-Flow, retains the graph convolution operations while being equipped with a Gaussian mixture representation space. It enjoys two benefits: it not only maintains the predictive power of GCN, but also produces well-separated clusters, due to the structuring of the representation space. We demonstrate these benefits on a variety of benchmark data sets. Moreover, we show that additional parameterization, such as that on the adjacency matrix used for graph convolutions, yields additional improvement in clustering.
@article{arxiv.2305.17284,
title = {GC-Flow: A Graph-Based Flow Network for Effective Clustering},
author = {Tianchun Wang and Farzaneh Mirzazadeh and Xiang Zhang and Jie Chen},
journal= {arXiv preprint arXiv:2305.17284},
year = {2023}
}
Comments
ICML 2023. Code is available at https://github.com/xztcwang/GCFlow