Extremal dependence of random scale constructions

Engelke, Sebastian; Opitz, Thomas; Wadsworth, Jennifer L.

doi:10.1007/s10687-019-00353-3

Cited by 28 publications

(33 citation statements)

References 41 publications

(78 reference statements)

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“…The process V E is assumed to possess hidden regular variation, with residual tail dependence coefficient satisfying η V ps 1 , s 2 q ă 1 for all s 1 ‰ s 2 . The resulting process X Ẽ is asymptotically independent for γ P p0, 1s and asymptotically dependent for γ ą 1; see also Engelke et al (2019) for related results.…”

Section: Mixing Independent Vectorsmentioning

confidence: 90%

“…In some of the examples below, it is convenient to establish a limit set and its gauge function using this observation rather than transforming to exactly exponential margins. Models with convenient dependence properties are often constructed through judicious combinations of random vectors with known dependence structures; see, for example, Engelke et al (2019) for a detailed study of so-called random scale or random location constructions. In Section 4.3, we use our results to elucidate the shape of the limit set when independent exponential-tailed variables are mixed additively.…”

Section: Examplesmentioning

confidence: 99%

See 1 more Smart Citation

Linking representations for multivariate extremes via a limit set

Nolde¹,

Wadsworth²

2020

Preprint

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The study of multivariate extremes is dominated by multivariate regular variation, although it is well known that this approach does not provide adequate distinction between random vectors whose components are not always simultaneously large. Various alternative dependence measures and representations have been proposed, with the most well-known being hidden regular variation and the conditional extreme value model. These varying depictions of extremal dependence arise through consideration of different parts of the multivariate domain, and particularly exploring what happens when extremes of one variable may grow at different rates to other variables. Thus far, these alternative representations have come from distinct sources and links between them are limited.In this work we elucidate many of the relevant connections through a geometrical approach. In particular, the shape of the limit set of scaled sample clouds in light-tailed margins is shown to provide a description of several different extremal dependence representations.

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Section: Mixing Independent Vectorsmentioning

confidence: 90%

Section: Examplesmentioning

confidence: 99%

Linking representations for multivariate extremes via a limit set

Nolde¹,

Wadsworth²

2020

Preprint

View full text Add to dashboard Cite

show abstract

“…Loosely speaking, heavier tailed R, impacting simultaneously the whole domain S, induces asymptotic dependence in X * , whereas lighter tailed R induces asymptotic independence. Engelke et al (2019) provide a fuller description of how extremal dependence of X * relates to the relative marginal tail heaviness of R and g(Z). Huser et al (2017) also used an identity link function, but placed few assumptions on the random scale, and provided more general results on the joint tail decay rates of the mixture processes.…”

Section: Spatial Dependence For Extremesmentioning

confidence: 99%

Hierarchical Transformed Scale Mixtures for Flexible Modeling of Spatial Extremes on Datasets With Many Locations

Zhang

Shaby

Wadsworth

2021

Journal of the American Statistical Association

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Flexible spatial models that allow transitions between tail dependence classes have recently appeared in the literature. However, inference for these models is computationally prohibitive, even in moderate dimensions, due to the necessity of repeatedly evaluating the multivariate Gaussian distribution function. In this work, we attempt to achieve truly high-dimensional inference for extremes of spatial processes, while retaining the desirable flexibility in the tail dependence structure, by modifying an established class of models based on scale mixtures Gaussian processes. We show that the desired extremal dependence properties from the original models are preserved under the modification, and demonstrate that the corresponding Bayesian hierarchical model does not involve the expensive computation of the multivariate Gaussian distribution function. We fit our model to exceedances of a high threshold, and perform coverage analyses and cross-model checks to validate its ability to capture different types of tail characteristics. We use a standard adaptive Metropolis algorithm for model fitting, and further accelerate the computation via parallelization and Rcpp.Lastly, we apply the model to a dataset of a fire threat index on the Great Plains region of the US, which is vulnerable to massively destructive wildfires. We find that the joint tail of the fire threat index exhibits a decaying dependence structure that cannot be captured by limiting extreme value models.

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“…A random vector X ∈ R d is called a scale mixture if it has the representation X = RW , where R is a non-negative univariate random variable and W ∈ R d is a random vector. Scale mixtures provide a flexible family of distributions that can capture both asymptotic dependence and independence depending on the specification of the tail of R and W ; see Huser et al (2017), Huser & Wadsworth (2019), Engelke et al (2019). In practice W is often taken as a Gaussian random vector and in this case X is termed a Gaussian scale mixture.…”

Section: Introductionmentioning

confidence: 99%

Modeling spatial extremes using normal mean-variance mixtures

Zhang¹,

Huser²,

Opitz³

et al. 2021

Preprint

Self Cite

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Classical models for multivariate or spatial extremes are mainly based upon the asymptotically justified max-stable or generalized Pareto processes. These models are suitable when asymptotic dependence is present, i.e., the joint tail decays at the same rate as the marginal tail. However, recent environmental data applications suggest that asymptotic independence is equally important and, unfortunately, existing spatial models in this setting that are both flexible and can be fitted efficiently are scarce. Here, we propose a new spatial copula model based on the generalized hyperbolic distribution, which is a specific normal mean-variance mixture and is very popular in financial modeling. The tail properties of this distribution have been studied in the literature, but with contradictory results. It turns out that the proofs from the literature contain mistakes. We here give a corrected theoretical description of its tail dependence structure and then exploit the model to analyze a simulated dataset from the inverted Brown-Resnick process, hindcast significant wave height data in the North Sea, and wind gust data in the state of Oklahoma, USA. We demonstrate that our proposed model is flexible enough to capture the dependence structure not only in the tail but also in the bulk.

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Extremal dependence of random scale constructions

Cited by 28 publications

References 41 publications

Linking representations for multivariate extremes via a limit set

Linking representations for multivariate extremes via a limit set

Hierarchical Transformed Scale Mixtures for Flexible Modeling of Spatial Extremes on Datasets With Many Locations

Modeling spatial extremes using normal mean-variance mixtures

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