Hidden tail chains and recurrence equations for dependence parameters associated with extremes of stationary higher-order Markov chains

School Of Mathematical Sciences

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Keywords

conditional extremes, extremal index, homogeneous and stationary Markov chain, recurrence equation, tail chain

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Hidden tail chains and recurrence equations for dependence parameters associated with extremes of stationary higher-order Markov chains. / Papastathopoulos, Ioannis; Casey, Adrian ; Tawn, Jonathan.
In: Advances in Applied Probability, Vol. 57, No. 2, 30.06.2025, p. 407-452.

Research output: Contribution to Journal/Magazine › Journal article › peer-review

Bibtex

@article{1ffbb166a9ef479caa3d36b7d7643344,

title = "Hidden tail chains and recurrence equations for dependence parameters associated with extremes of stationary higher-order Markov chains",

abstract = "We derive some key extremal features for stationary kth-order Markov chains that can be used to understand how the process moves between an extreme state and the body of the process. The chains are studied given that there is an exceedance of a threshold, as the threshold tends to the upper endpoint of the distribution. Unlike previous studies with k>1, we consider processes where standard limit theory describes each extreme event as a single observation without any information about the transition to and from the body of the distribution. Our work uses different asymptotic theory which results innon-degenerate limit laws for such processes. We study the extremal properties of the initial distribution and the transition probability kernel of the Markov chain under weak assumptions for broad classes of extremal dependence structures that cover both asymptotically dependent and asymptotically independent Markov chains. For chains with k>1, the transition of the chain away from the exceedance involves novel functions of the k previous states, in comparison to just the single value, when k=1. This leads to an increase in the complexity of determining the form of this class of functions, their properties and the method of their derivation in applications. We find that it is possible to derive an affine normalization, dependent on the threshold excess, such that non-degenerate limiting behaviour of the process, in the neighbourhood of the threshold excess, is assured for all lags. We find that these normalization functions have an attractive structure that has parallels to the Yule-Walker equations. Furthermore, the limiting process is always linear in the innovations. We illustrate the results with the study of kth order stationary Markov chains with exponential margins based on widely studied families of copula dependence structures.",

keywords = "conditional extremes, extremal index, homogeneous and stationary Markov chain, recurrence equation, tail chain",

author = "Ioannis Papastathopoulos and Adrian Casey and Jonathan Tawn",

year = "2024",

month = dec,

day = "2",

doi = "10.1017/apr.2024.47",

language = "English",

volume = "57",

pages = "407--452",

journal = "Advances in Applied Probability",

issn = "0001-8678",

publisher = "Cambridge University Press",

number = "2",

}

RIS

TY - JOUR

T1 - Hidden tail chains and recurrence equations for dependence parameters associated with extremes of stationary higher-order Markov chains

AU - Papastathopoulos, Ioannis

AU - Casey, Adrian

AU - Tawn, Jonathan

PY - 2024/12/2

Y1 - 2024/12/2

N2 - We derive some key extremal features for stationary kth-order Markov chains that can be used to understand how the process moves between an extreme state and the body of the process. The chains are studied given that there is an exceedance of a threshold, as the threshold tends to the upper endpoint of the distribution. Unlike previous studies with k>1, we consider processes where standard limit theory describes each extreme event as a single observation without any information about the transition to and from the body of the distribution. Our work uses different asymptotic theory which results innon-degenerate limit laws for such processes. We study the extremal properties of the initial distribution and the transition probability kernel of the Markov chain under weak assumptions for broad classes of extremal dependence structures that cover both asymptotically dependent and asymptotically independent Markov chains. For chains with k>1, the transition of the chain away from the exceedance involves novel functions of the k previous states, in comparison to just the single value, when k=1. This leads to an increase in the complexity of determining the form of this class of functions, their properties and the method of their derivation in applications. We find that it is possible to derive an affine normalization, dependent on the threshold excess, such that non-degenerate limiting behaviour of the process, in the neighbourhood of the threshold excess, is assured for all lags. We find that these normalization functions have an attractive structure that has parallels to the Yule-Walker equations. Furthermore, the limiting process is always linear in the innovations. We illustrate the results with the study of kth order stationary Markov chains with exponential margins based on widely studied families of copula dependence structures.

AB - We derive some key extremal features for stationary kth-order Markov chains that can be used to understand how the process moves between an extreme state and the body of the process. The chains are studied given that there is an exceedance of a threshold, as the threshold tends to the upper endpoint of the distribution. Unlike previous studies with k>1, we consider processes where standard limit theory describes each extreme event as a single observation without any information about the transition to and from the body of the distribution. Our work uses different asymptotic theory which results innon-degenerate limit laws for such processes. We study the extremal properties of the initial distribution and the transition probability kernel of the Markov chain under weak assumptions for broad classes of extremal dependence structures that cover both asymptotically dependent and asymptotically independent Markov chains. For chains with k>1, the transition of the chain away from the exceedance involves novel functions of the k previous states, in comparison to just the single value, when k=1. This leads to an increase in the complexity of determining the form of this class of functions, their properties and the method of their derivation in applications. We find that it is possible to derive an affine normalization, dependent on the threshold excess, such that non-degenerate limiting behaviour of the process, in the neighbourhood of the threshold excess, is assured for all lags. We find that these normalization functions have an attractive structure that has parallels to the Yule-Walker equations. Furthermore, the limiting process is always linear in the innovations. We illustrate the results with the study of kth order stationary Markov chains with exponential margins based on widely studied families of copula dependence structures.

KW - conditional extremes

KW - extremal index

KW - homogeneous and stationary Markov chain

KW - recurrence equation

KW - tail chain

U2 - 10.1017/apr.2024.47

DO - 10.1017/apr.2024.47

M3 - Journal article

VL - 57

SP - 407

EP - 452

JO - Advances in Applied Probability

JF - Advances in Applied Probability

SN - 0001-8678

IS - 2

ER -

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