English

Trimmed L\'evy Processes and their Extremal Components

Probability 2018-02-28 v1

Abstract

We analyse a trimmed stochastic process of the form (r)Xt=Xti=1rΔt(i){}^{(r)}X_t= X_t - \sum_{i=1}^r \Delta_t^{(i)}, where (Xt)t0(X_t)_{t \geq 0} is a driftless subordinator on R\mathbb{R} with its jumps on [0,t][0,t] ordered as Δt(1)Δt(2) \Delta_t^{(1)}\ge \Delta_t^{(2)} \cdots. When rr\to\infty, both (r)Xt0{}^{(r)}X_t \to 0 and Δt(r)0\Delta_t^{(r)} \to 0 a.s. for each t>0t>0, and it is interesting to study the weak limiting behaviour of ((r)Xt,Δt(r))\bigl({}^{(r)}X_t, \Delta_t^{(r)}\bigr) in this case. We term this "large-trimming" behaviour. Concentrating on the case t=1t=1, we study joint convergence of ((r)X1,Δ1(r))\bigl({}^{(r)}X_1, \Delta_1^{(r)}\bigr) under linear normalization, assuming extreme value-related conditions on the L\'evy measure of XX which guarantee that Δ1(r)\Delta_1^{(r)} has a limit distribution with linear normalization. Allowing (r)X1{}^{(r)}X_1 to have random centering and scaling in a natural way, we show that ((r)X1,Δ1(r))\bigl({}^{(r)}X_1, \Delta_1^{(r)}\bigr) has a bivariate normal limiting distribution, as rr\to\infty; but replacing the random normalizations with natural deterministic ones produces non-normal limits which we can specify.

Keywords

Cite

@article{arxiv.1802.09814,
  title  = {Trimmed L\'evy Processes and their Extremal Components},
  author = {Yuguang Ipsen and Ross Maller and Sidney Resnick},
  journal= {arXiv preprint arXiv:1802.09814},
  year   = {2018}
}

Comments

19 pages

R2 v1 2026-06-23T00:34:54.666Z