English

Kaplan-Meier V- and U-statistics

Statistics Theory 2020-03-13 v2 Methodology Statistics Theory

Abstract

In this paper, we study Kaplan-Meier V- and U-statistics respectively defined as θ(F^n)=i,jK(X[i:n],X[j:n])WiWj\theta(\widehat{F}_n)=\sum_{i,j}K(X_{[i:n]},X_{[j:n]})W_iW_j and θU(F^n)=ijK(X[i:n],X[j:n])WiWj/ijWiWj\theta_U(\widehat{F}_n)=\sum_{i\neq j}K(X_{[i:n]},X_{[j:n]})W_iW_j/\sum_{i\neq j}W_iW_j, where F^n\widehat{F}_n is the Kaplan-Meier estimator, {W1,,Wn}\{W_1,\ldots,W_n\} are the Kaplan-Meier weights and K:(0,)2RK:(0,\infty)^2\to\mathbb R is a symmetric kernel. As in the canonical setting of uncensored data, we differentiate between two asymptotic behaviours for θ(F^n)\theta(\widehat{F}_n) and θU(F^n)\theta_U(\widehat{F}_n). Additionally, we derive an asymptotic canonical V-statistic representation of the Kaplan-Meier V- and U-statistics. By using this representation we study properties of the asymptotic distribution. Applications to hypothesis testing are given.

Cite

@article{arxiv.1810.04806,
  title  = {Kaplan-Meier V- and U-statistics},
  author = {Tamara Fernández and Nicolás Rivera},
  journal= {arXiv preprint arXiv:1810.04806},
  year   = {2020}
}
R2 v1 2026-06-23T04:35:39.376Z