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A phase transition in the random transposition random walk

概率论 2007-05-23 v2 组合数学

摘要

Our work is motivated by Bourque and Pevzner's (2002) simulation study of the effectiveness of the parsimony method in studying genome rearrangement, and leads to a surprising result about the random transposition walk on the group of permutations on nn elements. Consider this walk in continuous time starting at the identity and let DtD_t be the minimum number of transpositions needed to go back to the identity from the location at time tt. DtD_t undergoes a phase transition: the distance Dcn/2u(c)nD_{cn/2} \sim u(c)n, where uu is an explicit function satisfying u(c)=c/2u(c)=c/2 for c1c \le 1 and u(c)1u(c)1. In other words, the distance to the identity is roughly linear during the subcritical phase, and after critical time n/2n/2 it becomes sublinear. In addition, we describe the fluctuations of Dcn/2D_{cn/2} about its mean in each of the threeregimes (subcritical, critical and supercritical). The techniques used involve viewing the cycles in the random permutation as a coagulation-fragmentation process and relating the behavior to the \Erd\H{o}s-Renyi random graph model.

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引用

@article{arxiv.math/0403259,
  title  = {A phase transition in the random transposition random walk},
  author = {Nathanael Berestycki and Rick Durrett},
  journal= {arXiv preprint arXiv:math/0403259},
  year   = {2007}
}

备注

Revisions include considerable changes in the presentation of section 6 (proof of the CLT in the supercritical regime), and several typos corrected. Also, the figures are now available as a separate .ps file