Sublinear Spectral Clustering Oracle with Little Memory
Abstract
We study the problem of designing \emph{sublinear spectral clustering oracles} for well-clusterable graphs. Such an oracle is an algorithm that, given query access to the adjacency list of a graph , first constructs a compact data structure that captures the clustering structure of . Once built, enables sublinear time responses to \textsc{WhichCluster} queries for any vertex . A major limitation of existing oracles is that constructing requires memory, which becomes a bottleneck for massive graphs and memory-limited settings. In this paper, we break this barrier and establish a memory-time trade-off for sublinear spectral clustering oracles. Specifically, for well-clusterable graphs, we present oracles that construct using much smaller than memory (e.g., ) while still answering membership queries in sublinear time. We also characterize the trade-off frontier between memory usage and query time , showing, for example, that for clusterable graphs with a logarithmic conductance gap, and we show that this trade-off is nearly optimal (up to logarithmic factors) for a natural class of approaches. Finally, to complement our theory, we validate the performance of our oracles through experiments on synthetic networks.
Cite
@article{arxiv.2604.14981,
title = {Sublinear Spectral Clustering Oracle with Little Memory},
author = {Ranran Shen and Xiaoyi Zhu and Pan Peng and Zengfeng Huang},
journal= {arXiv preprint arXiv:2604.14981},
year = {2026}
}
Comments
ICLR 2026