D. Buraczewski, Jeffrey F. Collamore, E. Damek, J. Zienkiewicz
{"title":"Large deviation estimates for exceedance times of perpetuity sequences and their dual processes","authors":"D. Buraczewski, Jeffrey F. Collamore, E. Damek, J. Zienkiewicz","doi":"10.1214/15-AOP1059","DOIUrl":null,"url":null,"abstract":"In a variety of problems in pure and applied probability, it is relevant to study the large exceedance probabilities of the perpetuity sequence Yn:=B1+A1B2+⋯+(A1⋯An−1)BnYn:=B1+A1B2+⋯+(A1⋯An−1)Bn, where (Ai,Bi)⊂(0,∞)×R(Ai,Bi)⊂(0,∞)×R. Estimates for the stationary tail distribution of {Yn}{Yn} have been developed in the seminal papers of Kesten [Acta Math. 131 (1973) 207–248] and Goldie [Ann. Appl. Probab. 1 (1991) 126–166]. Specifically, it is well known that if M:=supnYnM:=supnYn, then P{M>u}∼CMu−ξP{M>u}∼CMu−ξ as u→∞u→∞. While much attention has been focused on extending such estimates to more general settings, little work has been devoted to understanding the path behavior of these processes. In this paper, we derive sharp asymptotic estimates for the normalized first passage time Tu:=(logu)−1inf{n:Yn>u}Tu:=(logu)−1inf{n:Yn>u}. We begin by showing that, conditional on {Tu<∞}{Tu<∞}, Tu→ρTu→ρ as u→∞u→∞ for a certain positive constant ρρ. We then provide a conditional central limit theorem for {Tu}{Tu}, and study P{Tu∈G}P{Tu∈G} as u→∞u→∞ for sets G⊂[0,∞)G⊂[0,∞). If G⊂[0,ρ)G⊂[0,ρ), then we show that P{Tu∈G}uI(G)→C(G)P{Tu∈G}uI(G)→C(G) as u→∞u→∞ for a certain large deviation rate function II and constant C(G)C(G). On the other hand, if G⊂(ρ,∞)G⊂(ρ,∞), then we show that the tail behavior is actually quite complex and different asymptotic regimes are possible. We conclude by extending our results to the corresponding forward process, understood in the sense of Letac [In Random Matrices and Their Applications (Brunswick, Maine, 1984) (1986) 263–273 Amer. Math. Soc.], namely to the reflected process M∗n:=max{AnM∗n−1+Bn,0}Mn∗:=max{AnMn−1∗+Bn,0}, n∈Z+n∈Z+. Using Siegmund duality, we relate the first passage times of {Yn}{Yn} to the finite-time exceedance probabilities of {M∗n}{Mn∗}, yielding a new result concerning the convergence of {M∗n}{Mn∗} to its stationary distribution.","PeriodicalId":50763,"journal":{"name":"Annals of Probability","volume":null,"pages":null},"PeriodicalIF":2.1000,"publicationDate":"2014-11-27","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://sci-hub-pdf.com/10.1214/15-AOP1059","citationCount":"26","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Annals of Probability","FirstCategoryId":"100","ListUrlMain":"https://doi.org/10.1214/15-AOP1059","RegionNum":1,"RegionCategory":"数学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"STATISTICS & PROBABILITY","Score":null,"Total":0}
引用次数: 26
Abstract
In a variety of problems in pure and applied probability, it is relevant to study the large exceedance probabilities of the perpetuity sequence Yn:=B1+A1B2+⋯+(A1⋯An−1)BnYn:=B1+A1B2+⋯+(A1⋯An−1)Bn, where (Ai,Bi)⊂(0,∞)×R(Ai,Bi)⊂(0,∞)×R. Estimates for the stationary tail distribution of {Yn}{Yn} have been developed in the seminal papers of Kesten [Acta Math. 131 (1973) 207–248] and Goldie [Ann. Appl. Probab. 1 (1991) 126–166]. Specifically, it is well known that if M:=supnYnM:=supnYn, then P{M>u}∼CMu−ξP{M>u}∼CMu−ξ as u→∞u→∞. While much attention has been focused on extending such estimates to more general settings, little work has been devoted to understanding the path behavior of these processes. In this paper, we derive sharp asymptotic estimates for the normalized first passage time Tu:=(logu)−1inf{n:Yn>u}Tu:=(logu)−1inf{n:Yn>u}. We begin by showing that, conditional on {Tu<∞}{Tu<∞}, Tu→ρTu→ρ as u→∞u→∞ for a certain positive constant ρρ. We then provide a conditional central limit theorem for {Tu}{Tu}, and study P{Tu∈G}P{Tu∈G} as u→∞u→∞ for sets G⊂[0,∞)G⊂[0,∞). If G⊂[0,ρ)G⊂[0,ρ), then we show that P{Tu∈G}uI(G)→C(G)P{Tu∈G}uI(G)→C(G) as u→∞u→∞ for a certain large deviation rate function II and constant C(G)C(G). On the other hand, if G⊂(ρ,∞)G⊂(ρ,∞), then we show that the tail behavior is actually quite complex and different asymptotic regimes are possible. We conclude by extending our results to the corresponding forward process, understood in the sense of Letac [In Random Matrices and Their Applications (Brunswick, Maine, 1984) (1986) 263–273 Amer. Math. Soc.], namely to the reflected process M∗n:=max{AnM∗n−1+Bn,0}Mn∗:=max{AnMn−1∗+Bn,0}, n∈Z+n∈Z+. Using Siegmund duality, we relate the first passage times of {Yn}{Yn} to the finite-time exceedance probabilities of {M∗n}{Mn∗}, yielding a new result concerning the convergence of {M∗n}{Mn∗} to its stationary distribution.
期刊介绍:
The Annals of Probability publishes research papers in modern probability theory, its relations to other areas of mathematics, and its applications in the physical and biological sciences. Emphasis is on importance, interest, and originality – formal novelty and correctness are not sufficient for publication. The Annals will also publish authoritative review papers and surveys of areas in vigorous development.