English

Improved Upper Bound for the Size of a Trifferent Code

Information Theory 2024-02-06 v1 Discrete Mathematics Combinatorics math.IT

Abstract

A subset C{0,1,2}n\mathcal{C}\subseteq\{0,1,2\}^n is said to be a trifferent\textit{trifferent} code (of block length nn) if for every three distinct codewords x,y,zCx,y, z \in \mathcal{C}, there is a coordinate i{1,2,,n}i\in \{1,2,\ldots,n\} where they all differ, that is, {x(i),y(i),z(i)}\{x(i),y(i),z(i)\} is same as {0,1,2}\{0,1,2\}. Let T(n)T(n) denote the size of the largest trifferent code of block length nn. Understanding the asymptotic behavior of T(n)T(n) is closely related to determining the zero-error capacity of the (3/2)(3/2)-channel defined by Elias'88, and is a long-standing open problem in the area. Elias had shown that T(n)2×(3/2)nT(n)\leq 2\times (3/2)^n and prior to our work the best upper bound was T(n)0.6937×(3/2)nT(n)\leq 0.6937 \times (3/2)^n due to Kurz'23. We improve this bound to T(n)c×n2/5×(3/2)nT(n)\leq c \times n^{-2/5}\times (3/2)^n where cc is an absolute constant.

Keywords

Cite

@article{arxiv.2402.02390,
  title  = {Improved Upper Bound for the Size of a Trifferent Code},
  author = {Siddharth Bhandari and Abhishek Khetan},
  journal= {arXiv preprint arXiv:2402.02390},
  year   = {2024}
}

Comments

11 pages, 2 figures

R2 v1 2026-06-28T14:37:35.439Z