Fourier-based and Rational Graph Filters for Spectral Processing

TL;DR

This paper introduces a spectrum-free, rational polynomial-based approach for spectral graph filtering that improves accuracy and stability, applicable across various data types and applications.

Contribution

It proposes a novel spectrum-free method for graph filtering using rational polynomials, generalizing Fourier transforms to non-Euclidean domains.

Findings

More accurate and stable filter approximation with rational polynomials.

Spectrum-free computation reduces cost and storage.

Applicable to diverse data types and applications.

Abstract

Data are represented as graphs in a wide range of applications, such as Computer Vision (e.g., images) and Graphics (e.g., 3D meshes), network analysis (e.g., social networks), and bio-informatics (e.g., molecules). In this context, our overall goal is the definition of novel Fourier-based and graph filters induced by rational polynomials for graph processing, which generalise polynomial filters and the Fourier transform to non-Euclidean domains. For the efficient evaluation of discrete spectral Fourier-based and wavelet operators, we introduce a spectrum-free approach, which requires the solution of a small set of sparse, symmetric, well-conditioned linear systems and is oblivious of the evaluation of the Laplacian or kernel spectrum. Approximating arbitrary graph filters with rational polynomials provides a more accurate and numerically stable alternative with respect to polynomials. To achieve these goals, we also study the link between spectral operators, wavelets, and filtered convolution with integral operators induced by spectral kernels. According to our tests, main advantages of the proposed approach are (i) its generality with respect to the input data (e.g., graphs, 3D shapes), applications (e.g., signal reconstruction and smoothing, shape correspondence), and filters (e.g., polynomial, rational polynomial), and (ii) a spectrum-free computation with a generally low computational cost and storage overhead.