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Integrating experts' belief in upper tail inference for modelling of human-induced earthquake magnitudes

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Forthcoming

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Integrating experts' belief in upper tail inference for modelling of human-induced earthquake magnitudes. / Yue, Wanchen; Tawn, Jonathan; Towe, Ross et al.
In: Journal of Agricultural, Biological, and Environmental Statistics, 28.07.2025.

Research output: Contribution to Journal/MagazineJournal articlepeer-review

Harvard

Yue, W, Tawn, J, Towe, R & Varty, Z 2025, 'Integrating experts' belief in upper tail inference for modelling of human-induced earthquake magnitudes', Journal of Agricultural, Biological, and Environmental Statistics.

APA

Yue, W., Tawn, J., Towe, R., & Varty, Z. (in press). Integrating experts' belief in upper tail inference for modelling of human-induced earthquake magnitudes. Journal of Agricultural, Biological, and Environmental Statistics.

Vancouver

Yue W, Tawn J, Towe R, Varty Z. Integrating experts' belief in upper tail inference for modelling of human-induced earthquake magnitudes. Journal of Agricultural, Biological, and Environmental Statistics. 2025 Jul 28.

Author

Yue, Wanchen ; Tawn, Jonathan ; Towe, Ross et al. / Integrating experts' belief in upper tail inference for modelling of human-induced earthquake magnitudes. In: Journal of Agricultural, Biological, and Environmental Statistics. 2025.

Bibtex

@article{d2e3fbf4f8624a11aa8920e67f4fca3f,
title = "Integrating experts' belief in upper tail inference for modelling of human-induced earthquake magnitudes",
abstract = "Accurate estimation of the upper tail of a distribution is crucial in seismology, where estimating the probability of extreme earthquake magnitudes is vital for risk assessment and mitigation. Traditional statistical methods often overlook expert knowledge, particularly regarding physical upper bounds on earthquake magnitudes. This paper introduces a novel methodology for estimating the upper tail distribution, integrating experts' knowledge on the physical processes through a conservative bound on the worst possible earthquakes. The methodology combines rigorous statistical techniques with expert judgement, creating a hybrid model that complements existing data-driven methods and enhances the reliability of tail estimates. We demonstrate the benefits of incorporating experts' knowledge through the application to data on human-induced earthquakes in the Netherlands. Within this paper, we focus on seismological magnitude modelling, however, the proposed methodology has the potential to be implemented as a generic extreme value approach for multiple problem settings.",
author = "Wanchen Yue and Jonathan Tawn and Ross Towe and Zak Varty",
year = "2025",
month = jul,
day = "28",
language = "English",
journal = "Journal of Agricultural, Biological, and Environmental Statistics",
publisher = "Springer New York LLC",

}

RIS

TY - JOUR

T1 - Integrating experts' belief in upper tail inference for modelling of human-induced earthquake magnitudes

AU - Yue, Wanchen

AU - Tawn, Jonathan

AU - Towe, Ross

AU - Varty, Zak

PY - 2025/7/28

Y1 - 2025/7/28

N2 - Accurate estimation of the upper tail of a distribution is crucial in seismology, where estimating the probability of extreme earthquake magnitudes is vital for risk assessment and mitigation. Traditional statistical methods often overlook expert knowledge, particularly regarding physical upper bounds on earthquake magnitudes. This paper introduces a novel methodology for estimating the upper tail distribution, integrating experts' knowledge on the physical processes through a conservative bound on the worst possible earthquakes. The methodology combines rigorous statistical techniques with expert judgement, creating a hybrid model that complements existing data-driven methods and enhances the reliability of tail estimates. We demonstrate the benefits of incorporating experts' knowledge through the application to data on human-induced earthquakes in the Netherlands. Within this paper, we focus on seismological magnitude modelling, however, the proposed methodology has the potential to be implemented as a generic extreme value approach for multiple problem settings.

AB - Accurate estimation of the upper tail of a distribution is crucial in seismology, where estimating the probability of extreme earthquake magnitudes is vital for risk assessment and mitigation. Traditional statistical methods often overlook expert knowledge, particularly regarding physical upper bounds on earthquake magnitudes. This paper introduces a novel methodology for estimating the upper tail distribution, integrating experts' knowledge on the physical processes through a conservative bound on the worst possible earthquakes. The methodology combines rigorous statistical techniques with expert judgement, creating a hybrid model that complements existing data-driven methods and enhances the reliability of tail estimates. We demonstrate the benefits of incorporating experts' knowledge through the application to data on human-induced earthquakes in the Netherlands. Within this paper, we focus on seismological magnitude modelling, however, the proposed methodology has the potential to be implemented as a generic extreme value approach for multiple problem settings.

M3 - Journal article

JO - Journal of Agricultural, Biological, and Environmental Statistics

JF - Journal of Agricultural, Biological, and Environmental Statistics

ER -