Revisiting convolutional neural network on graphs with polynomial approximations of Laplace-Beltrami spectral filtering
This is an incremental study for graph neural network researchers, showing that certain operator changes may not enhance performance in specific biomedical applications.
The paper tackled the problem of improving graph convolutional neural networks by replacing the graph Laplacian with the Laplace-Beltrami operator and testing polynomial approximations, but found no improvement in classification accuracy for Alzheimer's disease brain image data, with all methods showing comparable performance.
This paper revisits spectral graph convolutional neural networks (graph-CNNs) given in Defferrard (2016) and develops the Laplace-Beltrami CNN (LB-CNN) by replacing the graph Laplacian with the LB operator. We then define spectral filters via the LB operator on a graph. We explore the feasibility of Chebyshev, Laguerre, and Hermite polynomials to approximate LB-based spectral filters and define an update of the LB operator for pooling in the LBCNN. We employ the brain image data from Alzheimer's Disease Neuroimaging Initiative (ADNI) and demonstrate the use of the proposed LB-CNN. Based on the cortical thickness of the ADNI dataset, we showed that the LB-CNN didn't improve classification accuracy compared to the spectral graph-CNN. The three polynomials had a similar computational cost and showed comparable classification accuracy in the LB-CNN or spectral graph-CNN. Our findings suggest that even though the shapes of the three polynomials are different, deep learning architecture allows us to learn spectral filters such that the classification performance is not dependent on the type of the polynomials or the operators (graph Laplacian and LB operator).