Probabilistic existence results for separable codes

Abstract

Separable codes were defined by Cheng and Miao in 2011, motivated by applications to the identification of pirates in a multimedia setting. Combinatorially, t-separable codes lie somewhere between t-frameproof and (t-1)-frameproof codes: all t-frameproof codes are t-separable, and all t-separable codes are (t-1)-frameproof. Results for frameproof codes show that (when q is large) there are q-ary t-separable codes of length n with approximately q n/t codewords, and that no q-ary t-separable codes of length n can have more than approximately q n/(t-1) codewords. The paper provides improved probabilistic existence results for t-separable codes when t≥ 3. More precisely, for all t≥ 3 and all n≥ 3, there exists a constant (depending only on t and n) such that there exists a q-ary t-separable code of length n with at least qn/(t-1) codewords for all sufficiently large integers q. This shows, in particular, that the upper bound (derived from the bound on (t-1)-frameproof codes) on the number of codewords in a t-separable code is realistic. The results above are more surprising after examining the situation when t=2. Results due to Gao and Ge show that a q-ary 2-separable code of length n can contain at most 32q2 n/3-12q n/3 codewords, and that codes with at least q2n/3 codewords exist. So optimal 2-separable codes behave neither like 2-frameproof nor 1-frameproof codes. Also, the Gao--Ge bound is strengthened to show that a q-ary 2-separable code of length n can have at most \[ q 2n/3+12q n/3(q n/3-1) \] codewords.