Title
Locally Decodable Codes From Nice Subsets of Finite Fields and Prime Factors of Mersenne Numbers
Abstract
A $k$-query Locally Decodable Code (LDC) encodes an $n$-bitmessage $x$ as an $N$-bit codeword $C(x),$ such that one can probabilistically recover any bit $x_i$ of the message by querying only $k$ bits of the codeword $C(x)$, even after some constant fraction of codeword bits has been corrupted. The major goal of LDC related research is to establish the optimal trade-off between length and query complexity of such codes. Recently upper bounds for the length of LDCs were vastly improved via constructions that rely on existence of certain special (nice) subsets of finite fields. In this work we extend the constructions of LDCs from nice subsets. We argue that further progress on upperbounds for LDCs via these methods is tied to progress on an old number theory question regarding the size of the largest prime factors of Mersenne numbers. Specifically, we show that every Mersenne number $m = 2^t - 1$ that has a prime factor $p m^{\gamma}$ yields a family of $k(\gamma)$-query locally decodable codes of length $\exp\left(n^{1/t}\right).$ Conversely, if for some fixed $k$ and all $\epsilon0$ one can use the nice subsets technique to obtain a family of $k$-query LDCs of length $\exp\left(n^\ epsilon\right);$ then infinitely many Mersenne numbers have prime factors larger than known currently.
Year
DOI
Venue
2009
10.1137/070696519
SIAM Journal on Computing
Keywords
DocType
Volume
mersenne primes,finite field,locally decodable code
Journal
38
Issue
ISSN
Citations 
5
1093-0159
11
PageRank 
References 
Authors
0.62
16
2
Name
Order
Citations
PageRank
Kiran S. Kedlaya110412.08
Sergey Yekhanin298352.33