High rate locally-correctable and locally-testable codes with sub-polynomial query complexity
Abstract
In this work, we construct the first locally-correctable codes (LCCs), and locally-testable codes (LTCs) with constant rate, constant relative distance, and sub-polynomial query complexity. Specifically, we show that there exist binary LCCs and LTCs with block length , constant rate (which can even be taken arbitrarily close to 1), constant relative distance, and query complexity . Previously such codes were known to exist only with query complexity (for constant ), and there were several, quite different, constructions known. Our codes are based on a general distance-amplification method of Alon and Luby~\cite{AL96_codes}. We show that this method interacts well with local correctors and testers, and obtain our main results by applying it to suitably constructed LCCs and LTCs in the non-standard regime of \emph{sub-constant relative distance}. Along the way, we also construct LCCs and LTCs over large alphabets, with the same query complexity , which additionally have the property of approaching the Singleton bound: they have almost the best-possible relationship between their rate and distance. This has the surprising consequence that asking for a large alphabet error-correcting code to further be an LCC or LTC with query complexity does not require any sacrifice in terms of rate and distance! Such a result was previously not known for any query complexity. Our results on LCCs also immediately give locally-decodable codes (LDCs) with the same parameters.
Cite
@article{arxiv.1504.05653,
title = {High rate locally-correctable and locally-testable codes with sub-polynomial query complexity},
author = {Swastik Kopparty and Or Meir and Noga Ron-Zewi and Shubhangi Saraf},
journal= {arXiv preprint arXiv:1504.05653},
year = {2015}
}