Scalable $M$-Channel Critically Sampled Filter Banks for Graph Signals

TL;DR

This paper introduces a scalable, critically sampled filter bank for graph signals that enables perfect reconstruction, efficient processing of large graphs, and provides a fast approximate graph Fourier transform with spectral coarse resolution.

Contribution

The paper proposes a novel $M$-channel critically sampled filter bank for graph signals, including scalable algorithms and analysis of properties like sparsity and localization.

Findings

Achieves perfect reconstruction of graph signals from analysis coefficients.

Provides a fast approximate graph Fourier transform with coarse spectral resolution.

Demonstrates effective compression of piecewise-smooth graph signals.

Abstract

We investigate a scalable $M$-channel critically sampled filter bank for graph signals, where each of the $M$ filters is supported on a different subband of the graph Laplacian spectrum. For analysis, the graph signal is filtered on each subband and downsampled on a corresponding set of vertices. However, the classical synthesis filters are replaced with interpolation operators. For small graphs, we use a full eigendecomposition of the graph Laplacian to partition the graph vertices such that the $m^{th}$ set comprises a uniqueness set for signals supported on the $m^{th}$ subband. The resulting transform is critically sampled, the dictionary atoms are orthogonal to those supported on different bands, and graph signals are perfectly reconstructable from their analysis coefficients. We also investigate fast versions of the proposed transform that scale efficiently for large, sparse graphs. Issues that arise in this context include designing the filter bank to be more amenable to polynomial approximation, estimating the number of samples required for each band, performing non-uniform random sampling for the filtered signals on each band, and using efficient reconstruction methods. We empirically explore the joint vertex-frequency localization of the dictionary atoms, the sparsity of the analysis coefficients for different classes of signals, the reconstruction error resulting from the numerical approximations, and the ability of the proposed transform to compress piecewise-smooth graph signals. The proposed filter bank also yields a fast, approximate graph Fourier transform with a coarse resolution in the spectral domain.