Locally Testable Codes and Cayley Graphs
Abstract
We give two new characterizations of (-linear) locally testable error-correcting codes in terms of Cayley graphs over : \begin{enumerate} \item A locally testable code is equivalent to a Cayley graph over whose set of generators is significantly larger than and has no short linear dependencies, but yields a shortest-path metric that embeds into with constant distortion. This extends and gives a converse to a result of Khot and Naor (2006), which showed that codes with large dual distance imply Cayley graphs that have no low-distortion embeddings into . \item A locally testable code is equivalent to a Cayley graph over that has significantly more than eigenvalues near 1, which have no short linear dependencies among them and which "explain" all of the large eigenvalues. This extends and gives a converse to a recent construction of Barak et al. (2012), which showed that locally testable codes imply Cayley graphs that are small-set expanders but have many large eigenvalues. \end{enumerate}
Keywords
Cite
@article{arxiv.1308.5158,
title = {Locally Testable Codes and Cayley Graphs},
author = {Parikshit Gopalan and Salil Vadhan and Yuan Zhou},
journal= {arXiv preprint arXiv:1308.5158},
year = {2013}
}
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22 pages