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A Sharp Discrepancy Bound for Jittered Sampling

Numerical Analysis 2022-06-13 v3 Computational Geometry Discrete Mathematics Numerical Analysis

Abstract

For m,dNm, d \in {\mathbb N}, a jittered sampling point set PP having N=mdN = m^d points in [0,1)d[0,1)^d is constructed by partitioning the unit cube [0,1)d[0,1)^d into mdm^d axis-aligned cubes of equal size and then placing one point independently and uniformly at random in each cube. We show that there are constants c0c \ge 0 and CC such that for all dd and all mdm \ge d the expected non-normalized star discrepancy of a jittered sampling point set satisfies cdmd121+log(md)ED(P)Cdmd121+log(md).c \,dm^{\frac{d-1}{2}} \sqrt{1 + \log(\tfrac md)} \le {\mathbb E} D^*(P) \le C\, dm^{\frac{d-1}{2}} \sqrt{1 + \log(\tfrac md)}. This discrepancy is thus smaller by a factor of Θ(1+log(m/d)m/d)\Theta\big(\sqrt{\frac{1+\log(m/d)}{m/d}}\,\big) than the one of a uniformly distributed random point set of mdm^d points. This result improves both the upper and the lower bound for the discrepancy of jittered sampling given by Pausinger and Steinerberger (Journal of Complexity (2016)). It also removes the asymptotic requirement that mm is sufficiently large compared to dd.

Keywords

Cite

@article{arxiv.2103.15712,
  title  = {A Sharp Discrepancy Bound for Jittered Sampling},
  author = {Benjamin Doerr},
  journal= {arXiv preprint arXiv:2103.15712},
  year   = {2022}
}
R2 v1 2026-06-24T00:39:21.796Z