Distance Metric Learning using Graph Convolutional Networks: Application to Functional Brain Networks
Abstract
Evaluating similarity between graphs is of major importance in several computer vision and pattern recognition problems, where graph representations are often used to model objects or interactions between elements. The choice of a distance or similarity metric is, however, not trivial and can be highly dependent on the application at hand. In this work, we propose a novel metric learning method to evaluate distance between graphs that leverages the power of convolutional neural networks, while exploiting concepts from spectral graph theory to allow these operations on irregular graphs. We demonstrate the potential of our method in the field of connectomics, where neuronal pathways or functional connections between brain regions are commonly modelled as graphs. In this problem, the definition of an appropriate graph similarity function is critical to unveil patterns of disruptions associated with certain brain disorders. Experimental results on the ABIDE dataset show that our method can learn a graph similarity metric tailored for a clinical application, improving the performance of a simple k-nn classifier by 11.9% compared to a traditional distance metric.
Cite
@article{arxiv.1703.02161,
title = {Distance Metric Learning using Graph Convolutional Networks: Application to Functional Brain Networks},
author = {Sofia Ira Ktena and Sarah Parisot and Enzo Ferrante and Martin Rajchl and Matthew Lee and Ben Glocker and Daniel Rueckert},
journal= {arXiv preprint arXiv:1703.02161},
year = {2017}
}
Comments
International Conference on Medical Image Computing and Computer-Assisted Interventions (MICCAI) 2017