Tight colorful no-dimensional Tverberg theorem

Abstract

We study colorful no-dimensional Tverberg-type problems and obtain several optimal results. A colorful no-dimensional Tverberg-type theorem provides a bound on a radius R such that, for any pairwise disjoint k-element subsets Q1,…,Qn of a normed space, there exists a partition of Q1·s Qn into disjoint transversals \P1,…,Pk\ for which a ball of radius R intersects the convex hull of each Pi (1 i k). Our methods are deterministic and dimension-free, and they are unified by optimizing two functionals: a quadratic selection functional whose local maximizers produce a complete system of disjoint transversals, and a convex intersection functional that certifies a common point. First, in the Euclidean setting we bound R in terms of the Chebyshev radii (minimal enclosing-ball radii) of the color classes Q1,…,Qn. A key observation is a ``combinatorial'' subadditivity of the squared Chebyshev radius: given sequences X=(x1,…,xk) and Y=(y1,…,yk) of points in a Euclidean space, contained in balls of radii RX and RY (not necessarily with the same center), one can reenumerate Y so that the pointwise-sum sequence Z=(x1+y1,…,xk+yk) is contained in a ball of radius RZ satisfying \[ RZ2 RX2 + RY2 . \] As a corollary, we obtain the best-possible bound \[ R 12nk-1k\, 1 i n diam(Qi). \] Our algorithm returns the desired disjoint transversals in overall time O(nk3). Second, we develop a complementary approach based on the inter-color diameter and extend the framework to obtain no-dimensional colorful Tverberg-type results in the hyperbolic setting and in Banach spaces.