Study of direct and inverse first-exit problems for drifted Brownian motion with Poissonian resetting

Abstract

We address some direct and inverse problems, for the first-exit time (FET) τ of a drifted Brownian motion with Poissonian resetting X(t) from an interval (0,b) and the first-exit area (FEA) A, namely the area swept out by X(t) till the time τ ; this type of diffusion process X(t) is characterized by the fact that a reset to the position xR can occur according to a homogeneous Poisson process with rate r>0. When the initial position X(0)= η ∈ (0,b) is deterministic and fixed, the direct FET problem consists in investigating the statistical properties of the FET τ , whilst the direct FEA problem studies the probability distribution of the FEA A. The inverse FET problem regards the case when η is randomly distributed in (0,b) (while r and xR are fixed); if F(t) is a given distribution function on the time t axis, the inverse FET problem consists in finding the density g of η, if it exists, such that P[τ t ] = F(t), \ t >0. %In addition to the case of random initial position η, we also study the case when the initial position η and the resetting rate r are fixed, whereas the reset position xR is random. Several explicit examples of solutions to the inverse FET problem are provided.

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