改进的不同代码大小的上界

IF 1 2区数学 Q1 MATHEMATICS

Combinatorica Pub Date : 2024-12-18 DOI:10.1007/s00493-024-00130-2

Siddharth Bhandari, Abhishek Khetan

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引用次数: 0

摘要

如果对于每三个不同的编码词（x,y、z）中，有一个坐标（i/in \{1,2,\ldots ,n/}）它们都不同，也就是说，（{x(i),y(i),z(i)）与（{0,1,2}）相同。了解 T(n) 的渐近行为与确定 Elias 定义的 (3/2)-channel 的零误码容量密切相关（IEEE Trans Inform Theory 34(5):1070-1074, 1988），这也是该领域一个长期未决的问题。埃利亚斯证明了（T(n)）是（3/2）^n（）的2倍，而在我们的研究之前，库尔兹（Example Counterexample 5:100139, 2024）提出的最佳上界是（T(n)）是（3/2）^n（）的0.6937倍。我们将这个界限改进为 \(T(n)\le c \times n^{-2/5}\times (3/2)^n\) 其中 c 是一个绝对常数。

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Improved Upper Bound for the Size of a Trifferent Code

A subset \(\mathcal {C}\subseteq \{0,1,2\}^n\) is said to be a trifferent code (of block length n) if for every three distinct codewords \(x,y, z \in \mathcal {C}\), there is a coordinate \(i\in \{1,2,\ldots ,n\}\) where they all differ, that is, \(\{x(i),y(i),z(i)\}\) is same as \(\{0,1,2\}\). Let T(n) denote the size of the largest trifferent code of block length n. Understanding the asymptotic behavior of T(n) is closely related to determining the zero-error capacity of the (3/2)-channel defined by Elias (IEEE Trans Inform Theory 34(5):1070–1074, 1988), and is a long-standing open problem in the area. Elias had shown that \(T(n)\le 2\times (3/2)^n\) and prior to our work the best upper bound was \(T(n)\le 0.6937 \times (3/2)^n\) due to Kurz (Example Counterexample 5:100139, 2024). We improve this bound to \(T(n)\le c \times n^{-2/5}\times (3/2)^n\) where c is an absolute constant.

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来源期刊

Combinatorica 数学-数学

CiteScore

1.90

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： COMBINATORICA publishes research papers in English in a variety of areas of combinatorics and the theory of computing, with particular emphasis on general techniques and unifying principles. Typical but not exclusive topics covered by COMBINATORICA are - Combinatorial structures (graphs, hypergraphs, matroids, designs, permutation groups). - Combinatorial optimization. - Combinatorial aspects of geometry and number theory. - Algorithms in combinatorics and related fields. - Computational complexity theory. - Randomization and explicit construction in combinatorics and algorithms.