Computational Lower Bounds for Correlated Random Graphs via Algorithmic Contiguity
Abstract
In this paper, assuming the low-degree conjecture, we provide evidence of computational hardness for two problems: (1) the (partial) matching recovery problem in the sparse correlated Erd\H{o}s-R\'enyi graphs when the edge-density and the correlation lies below the Otter's threshold, this resolves a remaining problem in \cite{DDL23+}; (2) the detection problem between a pair of correlated sparse stochastic block models and a pair of independent stochastic block models when lies below the Kesten-Stigum (KS) threshold and lies below the Otter's threshold, this resolves a remaining problem in \cite{CDGL24+}. One of the main ingredient in our proof is to derive certain forms of \emph{algorithmic contiguity} between two probability measures based on bounds on their low-degree advantage. To be more precise, consider the high-dimensional hypothesis testing problem between two probability measures and based on the sample . We show that if the low-degree advantage , then (assuming the low-degree conjecture) there is no efficient algorithm such that and . This framework provides a useful tool for performing reductions between different inference tasks, without requiring a strengthened version of the low-degree conjecture as in \cite{MW23+, DHSS25+}.
Keywords
Cite
@article{arxiv.2502.09832,
title = {Computational Lower Bounds for Correlated Random Graphs via Algorithmic Contiguity},
author = {Zhangsong Li},
journal= {arXiv preprint arXiv:2502.09832},
year = {2025}
}
Comments
This substantially improves the results and simplifies the proofs in an earlier version