Characterization of extendible distributions with exponential minima via processes that are infinitely divisible with respect to time
Document type:
Zeitschriftenaufsatz
Author(s):
Mai, J.-F.; Scherer, M.
Non-TUM Co-author(s):
nein
Cooperation:
-
Abstract:
We present a stochastic representation for multivariate extendible distributions with exponential minima (exEM), whose components are conditionally iid in the sense of de Finetti's theorem. It is shown that the "exponential minima property" is in one-to-one correspondence with the conditional cumulative hazard rate process being time-consistent infinitely divisible (TCID). The Laplace exponents of non- decreasing TCID processes are given in terms of a Bernstein function applied to the state variable and are linear in time. Examples for TCID processes comprise killed Lévy subordinators, monomials whose slope is randomized by a stable random variable, and several combinations thereof. As a byproduct of our results, we provide an alternative proof (and a mild generalization) of the important conclusion in [Genest, Rivest (1989)], stating that the only copula which is both Archimedean and of extreme-value kind is the Gumbel copula. Finally, we show that when the subfamily of strong TCID processes is used in the construction leading to exEM, the result is the proper subclass of extendible min-stable multivariate exponential (exMSMVE) distributions.
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We present a stochastic representation for multivariate extendible distributions with exponential minima (exEM), whose components are conditionally iid in the sense of de Finetti's theorem. It is shown that the "exponential minima property" is in one-to-one correspondence with the conditional cumulative hazard rate process being time-consistent infinitely divisible (TCID). The Laplace exponents of non- decreasing TCID processes are given in terms of a Bernstein function applied to the state vari...
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Keywords:
Distribution with exponential minima; MSMVE distribution; extreme-value copula; TCID process; Bernstein function; de Finetti's theorem.