This is the fourth in a series of papers devoted to the study of the
large deviations of a Wright –Fisher process modeling the genetic
evolution of a reproducing population.Variational considerations imply that if
the process undergoes a large deviation, then it necessarily follows closely a
definite path from its original to its current state. The favored paths were
determined previously for a one-dimensional process subject to one-way mutation
or natural selection, respectively, acting on a faster time scale than random
genetic drift. The present paper deals with a general $d$-dimensional
Wright–Fisher process in which any mutation or selection forces act on a
time scale no faster than that of genetic drift. If the states of the process
are represented as points on a $d$-sphere, then it can be shown that the
position of a subcritically scaled process at a fixed “time”
$T$ satisfies a large-deviation principle with rate function proportional
to the square of the length of the great circle arc joining this position with
the initial one (Hellinger–Bhattacharya distance). If a large deviation
does occur, then the process follows with near certainty this arc at constant
speed. The main technical problem circumvented is the degeneracy of the
covariance matrix of the process at the boundary of the state space.
Publié le : 2000-11-14
Classification:
Wright-Fisher process,
random genetic drift,
mutation,
natural selection,
large deviations,
rate function,
Hellinger-Bhattacharya distance,
60F10,
60J20
@article{1019487616,
author = {Papangelou, F.},
title = {The large deviations of a multi-allele Wright-Fisher process
mapped on the sphere},
journal = {Ann. Appl. Probab.},
volume = {10},
number = {2},
year = {2000},
pages = { 1259-1273},
language = {en},
url = {http://dml.mathdoc.fr/item/1019487616}
}
Papangelou, F. The large deviations of a multi-allele Wright-Fisher process
mapped on the sphere. Ann. Appl. Probab., Tome 10 (2000) no. 2, pp. 1259-1273. http://gdmltest.u-ga.fr/item/1019487616/