English

Bounds and Constructions for $\overline{3}$-Separable Codes with Length $3$

Information Theory 2015-07-06 v1 math.IT

Abstract

Separable codes were introduced to provide protection against illegal redistribution of copyrighted multimedia material. Let C\mathcal{C} be a code of length nn over an alphabet of qq letters. The descendant code desc(C0){\sf desc}(\mathcal{C}_0) of C0={c1,c2,,ct}C\mathcal{C}_0 = \{{\bf c}_1, {\bf c}_2, \ldots, {\bf c}_t\} \subseteq {\mathcal{C}} is defined to be the set of words x=(x1,x2,,xn)T{\bf x} = (x_1, x_2, \ldots,x_n)^T such that xi{c1,i,c2,i,,ct,i}x_i \in \{c_{1,i}, c_{2,i}, \ldots, c_{t,i}\} for all i=1,,ni=1, \ldots, n, where cj=(cj,1,cj,2,,cj,n)T{\bf c}_j=(c_{j,1},c_{j,2},\ldots,c_{j,n})^T. C\mathcal{C} is a t\overline{t}-separable code if for any two distinct C1,C2C\mathcal{C}_1, \mathcal{C}_2 \subseteq \mathcal{C} with C1t|\mathcal{C}_1| \le t, C2t|\mathcal{C}_2| \le t, we always have desc(C1)desc(C2){\sf desc}(\mathcal{C}_1) \neq {\sf desc}(\mathcal{C}_2). Let M(t,n,q)M(\overline{t},n,q) denote the maximal possible size of such a separable code. In this paper, an upper bound on M(3,3,q)M(\overline{3},3,q) is derived by considering an optimization problem related to a partial Latin square, and then two constructions for 3\overline{3}-SC(3,M,q)(3,M,q)s are provided by means of perfect hash families and Steiner triple systems.

Keywords

Cite

@article{arxiv.1507.00954,
  title  = {Bounds and Constructions for $\overline{3}$-Separable Codes with Length $3$},
  author = {Minquan Cheng and Jing Jiang and Haiyan Li and Ying Miao and Xiaohu Tang},
  journal= {arXiv preprint arXiv:1507.00954},
  year   = {2015}
}

Comments

19 pages

R2 v1 2026-06-22T10:05:20.412Z