Maxima of stationary systems of randomly time-changed Lévy particles

Abstract

In this work, we consider maxima of systems of randomly time-changed Lévy particles. We give a general construction to obtain infinite-dimensional classes \Zα\ of stationary max-infinitely divisible (max-id) processes. These classes are indexed by admissible mass functions α, which induce state-dependent time changes of the underlying Lévy particles. This gives a generalization of the well-known (Lévy--)Brown--Resnick process Z1. In contrast to α 1, the variability of non-constant mass functions α changes the dependence structure of the max-id process and goes beyond the max-stable setting while preserving stationarity. We then explore the extent of the so-called max-domain of attraction (MDA) of a given (Lévy--)Brown--Resnick process Z1, by studying convergence of rescaled maxima of independent copies of Zα to Z1. Thus, our work combines potential theory for Markov processes and extreme value theory to yield a novel, infinite-dimensional, and interpretable class \Zα\ of stationary processes in the MDA of a given (Lévy--)Brown--Resnick process Z1. So far, results on the extent of such domains have been scarce in the literature.