Semiparametric estimation for isotropic max-stable space-time processes

Sven Buhl; Richard A. Davis; Claudia Klüppelberg; Christina Steinkohl

doi:10.3150/18-BEJ1061

Semiparametric estimation for isotropic max-stable space-time processes

Sven Buhl
, Richard A. Davis
, Claudia Klüppelberg
, Christina Steinkohl

Chair of Mathematical Statistics

Technical University of Munich
Columbia University

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

7 Scopus citations

Abstract

Regularly varying space-time processes have proved useful to study extremal dependence in space-time data. We propose a semiparametric estimation procedure based on a closed form expression of the extremogram to estimate parametric models of extremal dependence functions. We establish the asymptotic properties of the resulting parameter estimates and propose subsampling procedures to obtain asymptotically correct confidence intervals. A simulation study shows that the proposed procedure works well for moderate sample sizes and is robust to small departures from the underlying model. Finally, we apply this estimation procedure to fitting a max-stable process to radar rainfall measurements in a region in Florida. Complementary results and some proofs of key results are presented together with the simulation study in the supplement [Buhl et al. (2018)].

Original language	English
Pages (from-to)	2508-2537
Number of pages	30
Journal	Bernoulli
Volume	25
Issue number	4 A
DOIs	https://doi.org/10.3150/18-BEJ1061
State	Published - 2019

Keywords

Brown-Resnick process
Extremogram
Max-stable process
Mixing
Regular variation
Semiparametric estimation
Space-time process
Subsampling

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10.3150/18-BEJ1061

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title = "Semiparametric estimation for isotropic max-stable space-time processes",

abstract = "Regularly varying space-time processes have proved useful to study extremal dependence in space-time data. We propose a semiparametric estimation procedure based on a closed form expression of the extremogram to estimate parametric models of extremal dependence functions. We establish the asymptotic properties of the resulting parameter estimates and propose subsampling procedures to obtain asymptotically correct confidence intervals. A simulation study shows that the proposed procedure works well for moderate sample sizes and is robust to small departures from the underlying model. Finally, we apply this estimation procedure to fitting a max-stable process to radar rainfall measurements in a region in Florida. Complementary results and some proofs of key results are presented together with the simulation study in the supplement [Buhl et al. (2018)].",

keywords = "Brown-Resnick process, Extremogram, Max-stable process, Mixing, Regular variation, Semiparametric estimation, Space-time process, Subsampling",

author = "Sven Buhl and Davis, \{Richard A.\} and Claudia Kl{\"u}ppelberg and Christina Steinkohl",

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doi = "10.3150/18-BEJ1061",

language = "English",

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TY - JOUR

T1 - Semiparametric estimation for isotropic max-stable space-time processes

AU - Buhl, Sven

AU - Davis, Richard A.

AU - Klüppelberg, Claudia

AU - Steinkohl, Christina

PY - 2019

Y1 - 2019

N2 - Regularly varying space-time processes have proved useful to study extremal dependence in space-time data. We propose a semiparametric estimation procedure based on a closed form expression of the extremogram to estimate parametric models of extremal dependence functions. We establish the asymptotic properties of the resulting parameter estimates and propose subsampling procedures to obtain asymptotically correct confidence intervals. A simulation study shows that the proposed procedure works well for moderate sample sizes and is robust to small departures from the underlying model. Finally, we apply this estimation procedure to fitting a max-stable process to radar rainfall measurements in a region in Florida. Complementary results and some proofs of key results are presented together with the simulation study in the supplement [Buhl et al. (2018)].

AB - Regularly varying space-time processes have proved useful to study extremal dependence in space-time data. We propose a semiparametric estimation procedure based on a closed form expression of the extremogram to estimate parametric models of extremal dependence functions. We establish the asymptotic properties of the resulting parameter estimates and propose subsampling procedures to obtain asymptotically correct confidence intervals. A simulation study shows that the proposed procedure works well for moderate sample sizes and is robust to small departures from the underlying model. Finally, we apply this estimation procedure to fitting a max-stable process to radar rainfall measurements in a region in Florida. Complementary results and some proofs of key results are presented together with the simulation study in the supplement [Buhl et al. (2018)].

KW - Brown-Resnick process

KW - Extremogram

KW - Max-stable process

KW - Mixing

KW - Regular variation

KW - Semiparametric estimation

KW - Space-time process

KW - Subsampling

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U2 - 10.3150/18-BEJ1061

DO - 10.3150/18-BEJ1061

M3 - Article

AN - SCOPUS:85072317892

SN - 1350-7265

VL - 25

SP - 2508

EP - 2537

JO - Bernoulli

JF - Bernoulli

IS - 4 A

ER -

Semiparametric estimation for isotropic max-stable space-time processes

Abstract

Keywords

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