English

Matching-Vector Families and LDCs Over Large Modulo

Combinatorics 2013-04-19 v2 Computational Complexity Discrete Mathematics

Abstract

We prove new upper bounds on the size of families of vectors in Zmn\Z_m^n with restricted modular inner products, when mm is a large integer. More formally, if u1,,utZmn\vec{u}_1,\ldots,\vec{u}_t \in \Z_m^n and v1,,vtZmn\vec{v}_1,\ldots,\vec{v}_t \in \Z_m^n satisfy ui,vi0(modm)\langle\vec{u}_i,\vec{v}_i\rangle\equiv0\pmod m and ui,vj≢0(modm)\langle\vec{u}_i,\vec{v}_j\rangle\not\equiv0\pmod m for all ij[t]i\neq j\in[t], we prove that tO(mn/2+8.47)t \leq O(m^{n/2+8.47}). This improves a recent bound of tmn/2+O(log(m))t \leq m^{n/2 + O(\log(m))} by \cite{BDL13} and is the best possible up to the constant 8.47 when mm is sufficiently larger than nn. The maximal size of such families, called `Matching-Vector families', shows up in recent constructions of locally decodable error correcting codes (LDCs) and determines the rate of the code. Using our result we are able to show that these codes, called Matching-Vector codes, must have encoding length at least K19/18K^{19/18} for KK-bit messages, regardless of their query complexity. This improves a known super linear bound of K2Ω(logK) K2^{\Omega({\sqrt{\log K}})} proved in \cite{DGY11}.

Keywords

Cite

@article{arxiv.1304.4819,
  title  = {Matching-Vector Families and LDCs Over Large Modulo},
  author = {Zeev Dvir and Guangda Hu},
  journal= {arXiv preprint arXiv:1304.4819},
  year   = {2013}
}
R2 v1 2026-06-22T00:01:38.590Z