On error rates in normal approximations and simulation schemes for Levy processes

Mikael Signahl

doi:10.1081/STM-120023562

On error rates in normal approximations and simulation schemes for Levy processes

Mikael Signahl

Mathematical Statistics

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

Abstract

Let X = (X(t) : t greater than or equal to 0) be a Levy process. In simulation, one often wants to know at what size it is possible to truncate the small jumps while retaining enough accuracy. A useful tool here is the Edgeworth expansion. We provide a third order expansion together with a uniform error bound, assuming third Levy moment is 0. We next discuss approximating X in the finite variation case. Truncating the small jumps, we show that, adding their expected value, and further, including their variability by approximating by a Brownian motion, gives successively better results in general. Finally, some numerical illustrations involving a normal inverse Gaussian Levy process are given.

Original language	English
Pages (from-to)	287-298
Journal	Stochastic Models
Volume	19
Issue number	3
DOIs	https://doi.org/10.1081/STM-120023562
Publication status	Published - 2003

Subject classification (UKÄ)

Probability Theory and Statistics

Free keywords

divisible distributions
infinitely
normal approximation
edgeworth expansion
weak error rates

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10.1081/STM-120023562

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title = "On error rates in normal approximations and simulation schemes for Levy processes",

abstract = "Let X = (X(t) : t greater than or equal to 0) be a Levy process. In simulation, one often wants to know at what size it is possible to truncate the small jumps while retaining enough accuracy. A useful tool here is the Edgeworth expansion. We provide a third order expansion together with a uniform error bound, assuming third Levy moment is 0. We next discuss approximating X in the finite variation case. Truncating the small jumps, we show that, adding their expected value, and further, including their variability by approximating by a Brownian motion, gives successively better results in general. Finally, some numerical illustrations involving a normal inverse Gaussian Levy process are given.",

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AB - Let X = (X(t) : t greater than or equal to 0) be a Levy process. In simulation, one often wants to know at what size it is possible to truncate the small jumps while retaining enough accuracy. A useful tool here is the Edgeworth expansion. We provide a third order expansion together with a uniform error bound, assuming third Levy moment is 0. We next discuss approximating X in the finite variation case. Truncating the small jumps, we show that, adding their expected value, and further, including their variability by approximating by a Brownian motion, gives successively better results in general. Finally, some numerical illustrations involving a normal inverse Gaussian Levy process are given.

KW - divisible distributions

KW - infinitely

KW - normal approximation

KW - edgeworth expansion

KW - weak error rates

U2 - 10.1081/STM-120023562

DO - 10.1081/STM-120023562

M3 - Article

SN - 1532-6349

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SP - 287

EP - 298

JO - Stochastic Models

JF - Stochastic Models

IS - 3

ER -

On error rates in normal approximations and simulation schemes for Levy processes

Abstract

Subject classification (UKÄ)

Free keywords

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