A Tverberg-type problem of Kalai: Two negative answers to questions of Alon and Smorodinsky, and the power of disjointness
Abstract
Let fr(d,s1,…,sr) denote the least integer n such that every n-point set P⊂eqRd admits a partition P=P1·s Pr with the property that for any choice of si-convex sets Ci⊃eq Pi (i∈[r]) one necessarily has i=1r Ci≠, where an si-convex set means a union of si convex sets. A recent breakthrough by Alon and Smorodinsky establishes a general upper bound fr(d,s1,…,sr) = O(dr2 r Πi=1r si· (Πi=1r si). Specializing to r=2 resolves the problem of Kalai from the 1970s. They further singled out two particularly intriguing questions: whether f2(2,s,s) can be improved from O(s2 s) to O(s), and whether fr(d,s,…,s) Poly(r,d,s). We answer both in the negative by showing the exponential lower bound fr(d,s,…,s)> sr for any r 2, s 1 and d 2r-2, which matches the upper bound up to a multiplicative s factor for sufficiently large s. Our construction combines a scalloped planar configuration with a direct product of regular s-gon on the high-dimensional torus (S1)r-2. Perhaps surprisingly, if we additionally require that within each block the si convex sets are pairwise disjoint, the picture changes markedly. Let Fr(d,s1,…,sr) denote this disjoint-union variant of the extremal function. We show: (1) F2(2,s,s)=O(s s) by connecting it to a suitable line-separating function in the plane; (2) when s is large, Fr(d,s,…,s) can be bounded by Or,d(s(1-12d(d+1))r+1) and Od(r3 r· s2d+3), respectively. This builds on a novel connection between the geometric obstruction and hypergraph Tur\'an numbers, in particular, a variant of the Erdos box problem.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.