Fractional Helly theorem for Cartesian products of convex sets

Abstract

Helly's theorem and its variants show that for a family of convex sets in Euclidean space, local intersection patterns influence global intersection patterns. A classical result of Eckhoff in 1988 provided an optimal fractional Helly theorem for axis-aligned boxes, which are Cartesian products of line segments. Answering a question raised by B\'ar\'any and Kalai, and independently Lew, we generalize Eckhoff's result to Cartesian products of convex sets in all dimensions. In particular, we prove that given α ∈ (1-1td,1] and a finite family F of Cartesian products of convex sets Πi∈[t]Ai in Rtd with Ai⊂ Rd if at least α-fraction of the (d+1)-tuples in F are intersecting then at least (1-(td(1-α))1/(d+1))-fraction of sets in F are intersecting. This is a special case of a more general result on intersections of d-Leray complexes. We also provide a construction showing that our result on d-Leray complexes is optimal. Interestingly the extremal example is representable as a family of cartesian products of convex sets, implying the bound α>1-1td and the fraction (1-(td(1-α))1/(d+1)) above are also best possible. The well-known optimal construction for fractional Helly theorem for convex sets in Rd does not have (p,d+1)-condition for sublinear p. Inspired by this we give constructions showing that, somewhat surprisingly, imposing additional (p,d+1)-condition has negligible effect on improving the quantitative bounds in neither the fractional Helly theorem for convex sets nor Cartesian products of convex sets. Our constructions offer a rich family of distinct extremal configurations for fractional Helly theorem, implying in a sense that the optimal bound is stable.