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Main Authors: Huang, Yushen, Luo, Ertai, Babenezhad, Reza, Sun, Yifan
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2503.16755
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author Huang, Yushen
Luo, Ertai
Babenezhad, Reza
Sun, Yifan
author_facet Huang, Yushen
Luo, Ertai
Babenezhad, Reza
Sun, Yifan
contents Large data applications rely on storing data in massive, sparse graphs with millions to trillions of nodes. Graph-based methods, such as node prediction, aim for computational efficiency regardless of graph size. Techniques like localized approximate personalized page rank (APPR) solve sparse linear systems with complexity independent of graph size, but is in terms of the maximum node degree, which can be much larger in practice than the average node degree for real-world large graphs. In this paper, we consider an \emph{online subsampled APPR method}, where messages are intentionally dropped at random. We use tools from graph sparsifiers and matrix linear algebra to give approximation bounds on the graph's spectral properties ($O(1/ε^2)$ edges), and node classification performance (added $O(nε)$ overhead).
format Preprint
id arxiv_https___arxiv_org_abs_2503_16755
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Fast online node labeling with graph subsampling
Huang, Yushen
Luo, Ertai
Babenezhad, Reza
Sun, Yifan
Data Structures and Algorithms
Machine Learning
Large data applications rely on storing data in massive, sparse graphs with millions to trillions of nodes. Graph-based methods, such as node prediction, aim for computational efficiency regardless of graph size. Techniques like localized approximate personalized page rank (APPR) solve sparse linear systems with complexity independent of graph size, but is in terms of the maximum node degree, which can be much larger in practice than the average node degree for real-world large graphs. In this paper, we consider an \emph{online subsampled APPR method}, where messages are intentionally dropped at random. We use tools from graph sparsifiers and matrix linear algebra to give approximation bounds on the graph's spectral properties ($O(1/ε^2)$ edges), and node classification performance (added $O(nε)$ overhead).
title Fast online node labeling with graph subsampling
topic Data Structures and Algorithms
Machine Learning
url https://arxiv.org/abs/2503.16755