Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Flexible covariate representations for extremes
Environmental extremes often show systematic variation with covariates. Three different nonparametric descriptions (penalized B‐splines, Bayesian adaptive regression splines, and Voronoi partition) for the dependence of extreme value model parameters on covariates are considered. These descriptions take the generic form of a linear combination of basis functions on the covariate domain, but differ (i) in the way that basis functions are constructed and possibly modified, and potentially (ii) by additional penalization of the variability (e.g., variance or roughness) of basis coefficients, for a given sample, to improve inference. The three representations are used to characterize variation of parameters in a nonstationary generalized Pareto model for the magnitude of threshold exceedances with respect to covariates. Computationally efficient schemes for Bayesian inference are used, including Riemann manifold Metropolis‐adjusted Langevin algorithm and reversible jump. A simulation study assesses relative performance of the three descriptions in estimating the distribution of the T‐year maximum event (for arbitrary T greater than the period of the sample) from a peaks over threshold extreme value analysis with respect to a single periodic covariate. The three descriptions are also used to estimate a directional tail model for peaks over threshold of storm peak significant wave height at a location in the northern North Sea.
Flexible covariate representations for extremes
Environmental extremes often show systematic variation with covariates. Three different nonparametric descriptions (penalized B‐splines, Bayesian adaptive regression splines, and Voronoi partition) for the dependence of extreme value model parameters on covariates are considered. These descriptions take the generic form of a linear combination of basis functions on the covariate domain, but differ (i) in the way that basis functions are constructed and possibly modified, and potentially (ii) by additional penalization of the variability (e.g., variance or roughness) of basis coefficients, for a given sample, to improve inference. The three representations are used to characterize variation of parameters in a nonstationary generalized Pareto model for the magnitude of threshold exceedances with respect to covariates. Computationally efficient schemes for Bayesian inference are used, including Riemann manifold Metropolis‐adjusted Langevin algorithm and reversible jump. A simulation study assesses relative performance of the three descriptions in estimating the distribution of the T‐year maximum event (for arbitrary T greater than the period of the sample) from a peaks over threshold extreme value analysis with respect to a single periodic covariate. The three descriptions are also used to estimate a directional tail model for peaks over threshold of storm peak significant wave height at a location in the northern North Sea.
Flexible covariate representations for extremes
Zanini, E. (Autor:in) / Eastoe, E. (Autor:in) / Jones, M. J. (Autor:in) / Randell, D. (Autor:in) / Jonathan, P. (Autor:in)
Environmetrics ; 31
01.08.2020
20 pages
Aufsatz (Zeitschrift)
Elektronische Ressource
Englisch
MCMC , return value , Voronoi , nonstationarity , ocean wave , Bayesian , extreme , generalized Pareto , mMALA , Poisson , covariate , spline , reversible jump , storm severity
Online Contents | 2012
| British Library Online Contents | 1998
| British Library Online Contents | 2004
MATERIAUTHEQUE - Milieux extrêmes
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