English

Nonparametric Estimation via Expected Order Statistics

Methodology 2026-05-26 v1

Abstract

The empirical distribution function assigns mass 1/n1/n to each of the nn observations in a sample. As these are highly variable, estimation error may be reduced by replacing them with estimated observations that are asymptotically less variable. Motivated by this idea, we introduce a nonparametric estimator obtained by assigning mass 1/m1/m to mm estimated expected order statistics, with mm chosen arbitrarily. The estimator enjoys several finite-sample properties and yields a rich asymptotic theory. Its estimation error relative to its population counterpart is controlled by the L1L^1 error of the empirical distribution. Moreover, every LL-functional of the new estimator corresponds to an LL-functional of the empirical distribution with updated weights. We establish almost sure convergence in LpL^p norm and Wasserstein distance as nn \to \infty, and derive weak convergence of the associated empirical quantile process in Lp(0,1)L^p(0,1), for p[1,)p\in[1,\infty) and mm fixed, and for p=1,2p=1,2 as n,mn,m \to \infty. These results yield asymptotic distributions for distance-based functionals, including LpL^p and Wasserstein metrics. Bootstrap validity is also established. Simulations show that the estimator often improves on the empirical distribution and remains competitive with kernel methods, with more stable performance across different distributional settings.

Keywords

Cite

@article{arxiv.2605.25897,
  title  = {Nonparametric Estimation via Expected Order Statistics},
  author = {Tommaso Lando and Lorenzo Tedesco},
  journal= {arXiv preprint arXiv:2605.25897},
  year   = {2026}
}