English

Boolean algebras and Lubell functions

Combinatorics 2013-07-15 v1

Abstract

Let 2[n]2^{[n]} denote the power set of [n]:={1,2,...,n}[n]:=\{1,2,..., n\}. A collection \B2[n]\B\subset 2^{[n]} forms a dd-dimensional {\em Boolean algebra} if there exist pairwise disjoint sets X0,X1,...,Xd[n]X_0, X_1,..., X_d \subseteq [n], all non-empty with perhaps the exception of X0X_0, so that \B=X0iIXi ⁣:I[d]\B={X_0\cup \bigcup_{i\in I} X_i\colon I\subseteq [d]}. Let b(n,d)b(n,d) be the maximum cardinality of a family \F2X\F\subset 2^X that does not contain a dd-dimensional Boolean algebra. Gunderson, R\"odl, and Sidorenko proved that b(n,d)cdn1/2d2nb(n,d) \leq c_d n^{-1/2^d} \cdot 2^n where cd=10d221ddd2dc_d= 10^d 2^{-2^{1-d}}d^{d-2^{-d}}. In this paper, we use the Lubell function as a new measurement for large families instead of cardinality. The Lubell value of a family of sets \F\F with \F\tsupn\F\subseteq \tsupn is defined by hn(\F):=F\F1/(nF)h_n(\F):=\sum_{F\in \F}1/{{n\choose |F|}}. We prove the following Tur\'an type theorem. If \F2[n]\F\subseteq 2^{[n]} contains no dd-dimensional Boolean algebra, then hn(\F)2(n+1)121dh_n(\F)\leq 2(n+1)^{1-2^{1-d}} for sufficiently large nn. This results implies b(n,d)Cn1/2d2nb(n,d) \leq C n^{-1/2^d} \cdot 2^n, where CC is an absolute constant independent of nn and dd. As a consequence, we improve several Ramsey-type bounds on Boolean algebras. We also prove a canonical Ramsey theorem for Boolean algebras.

Keywords

Cite

@article{arxiv.1307.3312,
  title  = {Boolean algebras and Lubell functions},
  author = {Travis Johnston and Linyuan Lu and Kevin G. Milans},
  journal= {arXiv preprint arXiv:1307.3312},
  year   = {2013}
}

Comments

10 pages

R2 v1 2026-06-22T00:50:11.192Z