Passage time and fluctuation calculations for subexponential Lévy processes

Ron Doney; Claudia Klüppelberg; Ross Maller

doi:10.3150/15-BEJ700

Passage time and fluctuation calculations for subexponential Lévy processes

Ron Doney, Claudia Klüppelberg, Ross Maller

Research output: Contribution to journal › Article › peer-review

5 Citations (Scopus)

Abstract

We consider the passage time problem for Lévy processes, emphasising heavy tailed cases. Results are obtained under quite mild assumptions, namely, drift to -∞a.s. of the process, possibly at a linear rate (the finite mean case), but possibly much faster (the infinite mean case), together with subexponential growth on the positive side. Local and functional versions of limit distributions are derived for the passage time itself, as well as for the position of the process just prior to passage, and the overshoot of a high level. A significant connection is made with extreme value theory via regular variation or maximum domain of attraction conditions imposed on the positive tail of the canonical measure, which are shown to be necessary for the kind of convergence behaviour we are interested in.

Original language	English
Pages (from-to)	1491-1519
Number of pages	29
Journal	Bernoulli
Volume	22
Issue number	3
DOIs	https://doi.org/10.3150/15-BEJ700
Publication status	Published - Aug 2016

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title = "Passage time and fluctuation calculations for subexponential L{\'e}vy processes",

abstract = "We consider the passage time problem for L{\'e}vy processes, emphasising heavy tailed cases. Results are obtained under quite mild assumptions, namely, drift to -∞a.s. of the process, possibly at a linear rate (the finite mean case), but possibly much faster (the infinite mean case), together with subexponential growth on the positive side. Local and functional versions of limit distributions are derived for the passage time itself, as well as for the position of the process just prior to passage, and the overshoot of a high level. A significant connection is made with extreme value theory via regular variation or maximum domain of attraction conditions imposed on the positive tail of the canonical measure, which are shown to be necessary for the kind of convergence behaviour we are interested in.",

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T1 - Passage time and fluctuation calculations for subexponential Lévy processes

AU - Doney, Ron

AU - Klüppelberg, Claudia

AU - Maller, Ross

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N2 - We consider the passage time problem for Lévy processes, emphasising heavy tailed cases. Results are obtained under quite mild assumptions, namely, drift to -∞a.s. of the process, possibly at a linear rate (the finite mean case), but possibly much faster (the infinite mean case), together with subexponential growth on the positive side. Local and functional versions of limit distributions are derived for the passage time itself, as well as for the position of the process just prior to passage, and the overshoot of a high level. A significant connection is made with extreme value theory via regular variation or maximum domain of attraction conditions imposed on the positive tail of the canonical measure, which are shown to be necessary for the kind of convergence behaviour we are interested in.

AB - We consider the passage time problem for Lévy processes, emphasising heavy tailed cases. Results are obtained under quite mild assumptions, namely, drift to -∞a.s. of the process, possibly at a linear rate (the finite mean case), but possibly much faster (the infinite mean case), together with subexponential growth on the positive side. Local and functional versions of limit distributions are derived for the passage time itself, as well as for the position of the process just prior to passage, and the overshoot of a high level. A significant connection is made with extreme value theory via regular variation or maximum domain of attraction conditions imposed on the positive tail of the canonical measure, which are shown to be necessary for the kind of convergence behaviour we are interested in.

KW - Fluctuation theory

KW - Lévy process

KW - Maximum domain of attraction

KW - Overshoot

KW - Passage time

KW - Regular variation

KW - Subexponential growth

KW - Undershoot

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Passage time and fluctuation calculations for subexponential Lévy processes

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