Exit times from time-dependent random domains: continuity, weak convergence, and exit-time profiles Draft -currently under review at Stochastic Processes and their Applications

Abstract

We study exit times from time-dependent domains under joint perturbations of the trajectory and the domain. Representing a moving domain by a continuous barrier on space-time, we reduce the exit problem to a one-dimensional first-passage problem for the scalarised path y(t) := (t,x(t)). Our first main result is a deterministic continuity theorem: the exit-time functional is continuous, under local Skorokhod J1 convergence of the path and local uniform convergence of the barrier, at every configuration satisfying an explicit non-tangency condition (NT). We show that NT is sharp in the sense that it characterises the continuity set of the functional. As a direct consequence, weak convergence of exit times follows from joint weak convergence of paths and barriers whenever the limiting pair satisfies NT almost surely; no independence or structural restrictions between trajectory and domain are required. Our second main result is a functional limit theorem: the exit-time profile uτ(u), viewed as a c\`adl\`ag function of the barrier level, converges in the Skorokhod M1 topology under the same hypotheses, with a concrete example showing that J1 convergence can fail. Concrete verification routes for NT are provided, including a non-characteristic/It\o criterion for diffusions, and the full framework is illustrated through a worked Donsker-type example.