Asymptotic Theory for the Maximum of an Increasing Sequence of Parametric Functions

Abstract

HillMotegi2017 present a new general asymptotic theory for the maximum of a random array \Xn(i) : 1 ≤ i ≤ L\n≥ 1, where each Xn(i) is assumed to converge in probability as n → ∞ . The array dimension L is allowed to increase with the sample size n. Existing extreme value theory arguments focus on observed data Xn(i), and require a well defined limit law for 1≤ i≤ L|Xn(i)| by restricting dependence across i. The high dimensional central limit theory literature presumes approximability by a Gaussian law, and also restricts attention to observed data. HillMotegi2017 do not require 1≤ i≤ Ln|Xn(i)| to have a well defined limit nor be approximable by a Gaussian random variable, and we do not make any assumptions about dependence across i. We apply the theory to filtered data when the variable of interest Xn(i,θ 0) is not observed, but its sample counterpart Xn(i,θn) is observed where θn estimates θ 0. The main results are illustrated by looking at unit root tests for a high dimensional random variable, and a residuals white noise test.