Geometry of Rounding: Near Optimal Bounds and a New Neighborhood Sperner's Lemma

Abstract

A partition P of Rd is called a (k,)-secluded partition if, for every p ∈ Rd, the ball B∞(, p) intersects at most k members of P. A goal in designing such secluded partitions is to minimize k while making as large as possible. This partition problem has connections to a diverse range of topics, including deterministic rounding schemes, pseudodeterminism, replicability, as well as Sperner/KKM-type results. In this work, we establish near-optimal relationships between k and . We show that, for any bounded measure partitions and for any d≥ 1, it must be that k≥(1+2)d. Thus, when k=k(d) is restricted to poly(d), it follows that =(d)∈ O( dd). This bound is tight up to log factors, as it is known that there exist secluded partitions with k(d)=d+1 and (d)=12d. We also provide new constructions of secluded partitions that work for a broad spectrum of k(d) and (d) parameters. Specifically, we prove that, for any f:N→N, there is a secluded partition with k(d)=(f(d)+1)df(d) and (d)=12f(d). These new partitions are optimal up to O( d) factors for various choices of k(d) and (d). Based on the lower bound result, we establish a new neighborhood version of Sperner's lemma over hypercubes, which is of independent interest. In addition, we prove a no-free-lunch theorem about the limitations of rounding schemes in the context of pseudodeterministic/replicable algorithms.