English

Chain Covers in the Boolean Lattice

Combinatorics 2026-06-28 v1

Abstract

For integers 1rn+11\le r\le n+1, let N(n,r)N(n,r) denote the least number of chains in the Boolean lattice Bn=2[n]B_n=2^{[n]} that cover every strict rr-term chain. The case r=1r=1 is the classical chain-decomposition problem and is generalizing Dilworth's theorem and Sperner's theorem. We study two complementary regimes. First, when r>1r>1 is fixed and nn\to\infty. Let M(n,r):=maxa0++ar=na0,ar0, ai1 (1ir1)(na0,,ar).M(n,r):= \max_{\substack{ a_0+\cdots+a_r=n a_0,a_r\ge 0,\ a_i\ge 1\ (1\le i\le r-1) }} \binom{n}{a_0,\ldots,a_r}. We prove that lower and upper bounds which differ only by a logarithmic factor: M(n,r)N(n,r)(r2+o(1))lognM(n,r). M(n,r)\le N(n,r)\le \left(\frac r2+o(1)\right)\log n\cdot M(n,r). Second, we consider the near-maximal regime N(n,nt)N(n,n-t), where t>0t>0 is fixed. We prove a general upper bound N(n,nt)n!t N(n,n-t)\le \frac{n!}{t} using the inversion number of the permutations modulo tt. This is exact for t=2t=2, giving N(n,n2)=n!/2N(n,n-2)=n!/2, and asymptotically exact for t=3t=3, giving N(n,n3)=(13+o(1))n!.N(n,n-3)=\left(\frac13+o(1)\right)n!. The matching lower bound for t=3t=3, and stronger lower bounds for all fixed tt, come from subcube-hitting problems originated from Kostochka and vertex-Tur\'an problems.

Cite

@article{arxiv.2606.29385,
  title  = {Chain Covers in the Boolean Lattice},
  author = {Zoltán Lóránt Nagy and Balázs Patkós},
  journal= {arXiv preprint arXiv:2606.29385},
  year   = {2026}
}