List Decoding Expander-Based Codes via Fast Approximation of Expanding CSPs: I
Abstract
We present near-linear time list decoding algorithms (in the block-length ) for expander-based code constructions. More precisely, we show that (i) For every and , there is an explicit family of good Tanner LDPC codes of (design) distance that is list decodable in time with alphabet size , (ii) For every and , there is an explicit family of AEL codes of rate , distance that is list decodable in time with alphabet size , and (iii) For every and , there is an explicit family of AEL codes of rate , distance that is list decodable in time with alphabet size using recent near-optimal list size bounds from [JMST25]. Our results are obtained by phrasing the decoding task as an agreement CSP [RWZ20,DHKNT19] on expander graphs and using the fast approximation algorithm for -ary expanding CSPs from [Jer23], which is based on weak regularity decomposition [JST21,FK96]. Similarly to list decoding -ary Ta-Shma's codes in [Jer23], we show that it suffices to enumerate over assignments that are constant in each part (of the constantly many) of the decomposition in order to recover all codewords in the list.
Cite
@article{arxiv.2509.05203,
title = {List Decoding Expander-Based Codes via Fast Approximation of Expanding CSPs: I},
author = {Fernando Granha Jeronimo and Aman Singh},
journal= {arXiv preprint arXiv:2509.05203},
year = {2025}
}