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Bibliographic Details
Main Authors: MacLaurin, James, Newby, Jay M.
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2309.01827
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author MacLaurin, James
Newby, Jay M.
author_facet MacLaurin, James
Newby, Jay M.
contents A collection of identical and independent rare event first passage times is considered. The problem of finding the fastest out of $N$ such events to occur is called an extreme first passage time. The rare event times are singular and limit to infinity as a positive parameter scaling the noise magnitude is reduced to zero. In contrast, previous work has shown that the mean of the fastest event time goes to zero in the limit of an infinite number of walkers. The combined limit is studied. In particular, the mean time and the most likely path taken by the fastest random walker are investigated. Using techniques from large deviation theory, it is shown that there is a distinguished limit where the mean time for the fastest walker can take any positive value, depending on a single proportionality constant. Furthermore, it is shown that the mean time and most likely path can be approximated using the solution to a variational problem related to the single-walker rare event.
format Preprint
id arxiv_https___arxiv_org_abs_2309_01827
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Extreme first passage times for populations of identical rare events
MacLaurin, James
Newby, Jay M.
Biological Physics
Probability
Subcellular Processes
A collection of identical and independent rare event first passage times is considered. The problem of finding the fastest out of $N$ such events to occur is called an extreme first passage time. The rare event times are singular and limit to infinity as a positive parameter scaling the noise magnitude is reduced to zero. In contrast, previous work has shown that the mean of the fastest event time goes to zero in the limit of an infinite number of walkers. The combined limit is studied. In particular, the mean time and the most likely path taken by the fastest random walker are investigated. Using techniques from large deviation theory, it is shown that there is a distinguished limit where the mean time for the fastest walker can take any positive value, depending on a single proportionality constant. Furthermore, it is shown that the mean time and most likely path can be approximated using the solution to a variational problem related to the single-walker rare event.
title Extreme first passage times for populations of identical rare events
topic Biological Physics
Probability
Subcellular Processes
url https://arxiv.org/abs/2309.01827