Decimated Framelet System on Graphs and Fast G-Framelet Transforms

Research output: Journal Publications and ReviewsRGC 21 - Publication in refereed journalpeer-review

15 Scopus Citations
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Detail(s)

Original languageEnglish
Article number18
Journal / PublicationJournal of Machine Learning Research
Volume23
Online publishedFeb 2022
Publication statusPublished - 2022

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Abstract

Graph representation learning has many real-world applications, from self-driving LiDAR, 3D computer vision to drug repurposing, protein classification, social networks analysis. An adequate representation of graph data is vital to the learning performance of a statistical or machine learning model for graph-structured data. This paper proposes a novel multiscale representation system for graph data, called decimated framelets, which form a localized tight frame on the graph. The decimated framelet system allows storage of the graph data representation on a coarse-grained chain and processes the graph data at multi scales where at each scale, the data is stored on a subgraph. Based on this, we establish decimated G-framelet transforms for the decomposition and reconstruction of the graph data at multi resolutions via a constructive data-driven filter bank. The graph framelets are built on a chain-based orthonormal basis that supports fast graph Fourier transforms. From this, we give a fast algorithm for the decimated G-framelet transforms, or FGT, that has linear computational complexity O (N) for a graph of size N. The effectiveness for constructing the decimated framelet system and the FGT is demonstrated by a simulated example of random graphs and real-world applications, including multiresolution analysis for traffic network and representation learning of graph neural networks for graph classification tasks.

Research Area(s)

  • Graphs, Decimated tight framelets, Tree, SPOC, Undecimated tight framelets, Filter bank, Fast G-framelet transforms, Fast Fourier transforms, Coarse-grained chain, Graph Laplacian, Haar basis, Graph convolution, Graph neural networks, Multiresolution analysis, NONLINEAR DIMENSIONALITY REDUCTION, NEEDLET APPROXIMATION, TIGHT FRAMELETS, AFFINE SYSTEMS, WAVELET, REPRESENTATION, LAPLACIAN, CONVOLUTION, L-2(R-D), SYMMETRY

Citation Format(s)

Decimated Framelet System on Graphs and Fast G-Framelet Transforms. / Zheng, Xuebin; Zhou, Bingxin; Wang, Yu Guang et al.
In: Journal of Machine Learning Research, Vol. 23, 18, 2022.

Research output: Journal Publications and ReviewsRGC 21 - Publication in refereed journalpeer-review

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