Vector Balancing in Lebesgue Spaces

Abstract

A tantalizing conjecture in discrete mathematics is the one of Koml\'os, suggesting that for any vectors a1,…,an ∈ B2m there exist signs x1, …, xn ∈ \ -1,1\ so that \|Σi=1n xiai\|∞ O(1). It is a natural extension to ask what q-norm bound to expect for a1,…,an ∈ Bpm. We prove that, for 2 p q ∞, such vectors admit fractional colorings x1, …, xn ∈ [-1,1] with a linear number of 1 coordinates so that \|Σi=1n xiai\|q ≤ O((p,(2m/n))) · n1/2-1/p+ 1/q, and that one can obtain a full coloring at the expense of another factor of 11/2 - 1/p + 1/q. In particular, for p ∈ (2,3] we can indeed find signs x ∈ \ -1,1\n with \|Σi=1n xiai\|∞ O(n1/2-1/p · 1p-2). Our result generalizes Spencer's theorem, for which p = q = ∞, and is tight for m = n. Additionally, we prove that for any fixed constant δ>0, in a centrally symmetric body K ⊂eq Rn with measure at least e-δ n one can find such a fractional coloring in polynomial time. Previously this was known only for a small enough constant -- indeed in this regime classical nonconstructive arguments do not apply and partial colorings of the form x ∈ \ -1,0,1\n do not necessarily exist.