English

Isotonic regression in general dimensions

Statistics Theory 2017-09-01 v1 Statistics Theory

Abstract

We study the least squares regression function estimator over the class of real-valued functions on [0,1]d[0,1]^d that are increasing in each coordinate. For uniformly bounded signals and with a fixed, cubic lattice design, we establish that the estimator achieves the minimax rate of order nmin{2/(d+2),1/d}n^{-\min\{2/(d+2),1/d\}} in the empirical L2L_2 loss, up to poly-logarithmic factors. Further, we prove a sharp oracle inequality, which reveals in particular that when the true regression function is piecewise constant on kk hyperrectangles, the least squares estimator enjoys a faster, adaptive rate of convergence of (k/n)min(1,2/d)(k/n)^{\min(1,2/d)}, again up to poly-logarithmic factors. Previous results are confined to the case d2d \leq 2. Finally, we establish corresponding bounds (which are new even in the case d=2d=2) in the more challenging random design setting. There are two surprising features of these results: first, they demonstrate that it is possible for a global empirical risk minimisation procedure to be rate optimal up to poly-logarithmic factors even when the corresponding entropy integral for the function class diverges rapidly; second, they indicate that the adaptation rate for shape-constrained estimators can be strictly worse than the parametric rate.

Keywords

Cite

@article{arxiv.1708.09468,
  title  = {Isotonic regression in general dimensions},
  author = {Qiyang Han and Tengyao Wang and Sabyasachi Chatterjee and Richard J. Samworth},
  journal= {arXiv preprint arXiv:1708.09468},
  year   = {2017}
}

Comments

36 pages

R2 v1 2026-06-22T21:28:28.747Z