English

Traces of Hypergraphs

Combinatorics 2018-09-25 v2

Abstract

Let Tr(n,m,k)\text{Tr}(n,m,k) denote the largest number of distinct projections onto kk coordinates guaranteed in any family of mm binary vectors of length nn. The classical Sauer-Perles-Shelah Lemma implies that Tr(n,nr,k)=2k\text{Tr}(n, n^r, k) = 2^k for krk \le r. While determining Tr(n,nr,k)\text{Tr}(n,n^r,k) precisely for general kk seems hopeless even for constant rr, estimating it, and more generally estimating the function Tr(n,m,k)\text{Tr}(n,m,k) for all range of the parameters, remains a widely open problem with connections to important questions in computer science and combinatorics. Here we essentially resolve this problem when kk is linear and m=nrm=n^r where rr is constant, proving that, for any constant α>0\alpha>0, Tr(n,nr,αn)=Θ~(nC)\text{Tr}(n,n^r,\alpha n) = \tilde\Theta(n^C) with C=C(r,α)=r+1log(1+α)2log(1+α)C=C(r,\alpha)=\frac{r+1-\log(1+\alpha)}{2-\log(1+\alpha)}. For the proof we establish a "sparse" version of another classical result, the Kruskal-Katona Theorem, which gives a stronger guarantee when the hypergraph does not induce dense sub-hypergraphs. Furthermore, we prove that the parameters in our sparse Kruskal-Katona theorem are essentially best possible. Finally, we mention two simple applications which may be of independent interest.

Keywords

Cite

@article{arxiv.1804.10717,
  title  = {Traces of Hypergraphs},
  author = {Noga Alon and Guy Moshkovitz and Noam Solomon},
  journal= {arXiv preprint arXiv:1804.10717},
  year   = {2018}
}
R2 v1 2026-06-23T01:38:43.684Z