Time to reach the maximum for a stationary stochastic process

Abstract

We consider a one-dimensional stationary time series of fixed duration T. We investigate the time t m at which the process reaches the global maximum within the time interval [0,T]. By using a path-decomposition technique, we compute the probability density function P(t m|T) of t m for several processes, that are either at equilibrium (such as the Ornstein-Uhlenbeck process) or out of equilibrium (such as Brownian motion with stochastic resetting). We show that for equilibrium processes the distribution of P(t m|T) is always symmetric around the midpoint t m=T/2, as a consequence of the time-reversal symmetry. This property can be used to detect nonequilibrium fluctuations in stationary time series. Moreover, for a diffusive particle in a confining potential, we show that the scaled distribution P(t m|T) becomes universal, i.e., independent of the details of the potential, at late times. This distribution P(t m|T) becomes uniform in the "bulk" 1 t m T and has a nontrivial universal shape in the "edge regimes" t m0 and t m T. Some of these results have been announced in a recent Letter [Europhys. Lett. 135, 30003 (2021)].

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