English

Concentration inequalities for a removal-driven thinning process

Probability 2017-04-28 v3

Abstract

We prove exponential concentration estimates and a strong law of large numbers for a particle system that is the simplest representative of a general class of models for 2D grain boundary coarsening. The system consists of nn particles in (0,)(0,\infty) that move at unit speed to the left. Each time a particle hits the boundary point 00, it is removed from the system along with a second particle chosen uniformly from the particles in (0,)(0,\infty). Under the assumption that the initial empirical measure of the particle system converges weakly to a measure with density f0(x)L+1(0,)f_0(x) \in L^1_+(0,\infty), the empirical measure of the particle system at time tt is shown to converge to the measure with density f(x,t)f(x,t), where ff is the unique solution to the kinetic equation with nonlinear boundary coupling tf(x,t)xf(x,t)=f(0,t)0f(y,t)dyf(x,t),0<x<,\partial_t f (x,t) - \partial_x f(x,t) = -\frac{f(0,t)}{\int_0^\infty f(y,t)\, dy} f(x,t), \quad 0<x < \infty, and initial condition f(x,0)=f0(x)f(x,0)=f_0(x). The proof relies on a concentration inequality for an urn model studied by Pittel, and Maurey's concentration inequality for Lipschitz functions on the permutation group.

Keywords

Cite

@article{arxiv.1608.02822,
  title  = {Concentration inequalities for a removal-driven thinning process},
  author = {Joe Klobusicky and Govind Menon},
  journal= {arXiv preprint arXiv:1608.02822},
  year   = {2017}
}

Comments

23 pages

R2 v1 2026-06-22T15:15:57.116Z