English

Set Families with Low Pairwise Intersection

Computational Complexity 2014-04-18 v1 Combinatorics

Abstract

A (n,,γ)\left(n,\ell,\gamma\right)-sharing set family of size mm is a family of sets S1,,Sm[n]S_1,\ldots,S_m\subseteq [n] s.t. each set has size \ell and each pair of sets shares at most γ\gamma elements. We let m(n,,γ)m\left(n,\ell,\gamma\right) denote the maximum size of any such set family and we consider the following question: How large can m(n,,γ)m\left(n,\ell,\gamma\right) be? (n,,γ)\left(n,\ell,\gamma\right)-sharing set families have a rich set of applications including the construction of pseudorandom number generators and usable and secure password management schemes. We analyze the explicit construction of Blocki et al using recent bounds on the value of the tt'th Ramanujan prime. We show that this explicit construction produces a (42ln4,,γ)\left(4\ell^2\ln 4\ell,\ell,\gamma\right)-sharing set family of size (2ln2)γ+1\left(2 \ell \ln 2\ell\right)^{\gamma+1} for any γ\ell\geq \gamma. We also show that the construction of Blocki et al can be used to obtain a weak (n,,γ)\left(n,\ell,\gamma\right)-sharing set family of size mm for any m>0m >0. These results are competitive with the inexplicit construction of Raz et al for weak (n,,γ)\left(n,\ell,\gamma\right)-sharing families. We show that our explicit construction of weak (n,,γ)\left(n,\ell,\gamma\right)-sharing set families can be used to obtain a parallelizable pseudorandom number generator with a low memory footprint by using the pseudorandom number generator of Nisan and Wigderson. We also prove that m(n,n/c1,c2n)m\left(n,n/c_1,c_2n\right) must be a constant whenever c22c13+c12c_2 \leq \frac{2}{c_1^3+c_1^2}. We show that this bound is nearly tight as m(n,n/c1,c2n)m\left(n,n/c_1,c_2n\right) grows exponentially fast whenever c2>c12c_2 > c_1^{-2}.

Cite

@article{arxiv.1404.4622,
  title  = {Set Families with Low Pairwise Intersection},
  author = {Calvin Beideman and Jeremiah Blocki},
  journal= {arXiv preprint arXiv:1404.4622},
  year   = {2014}
}
R2 v1 2026-06-22T03:53:17.430Z