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Bayesian hierarchical model for bias-correcting climate models

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Bayesian hierarchical model for bias-correcting climate models. / Carter, Jeremy; Chacón-Montalván, Erick A.; Leeson, Amber.
In: Geoscientific Model Development, Vol. 17, No. 14, 31.07.2024, p. 5733-5757.

Research output: Contribution to Journal/MagazineJournal articlepeer-review

Harvard

Carter, J, Chacón-Montalván, EA & Leeson, A 2024, 'Bayesian hierarchical model for bias-correcting climate models', Geoscientific Model Development, vol. 17, no. 14, pp. 5733-5757. https://doi.org/10.5194/gmd-17-5733-2024

APA

Carter, J., Chacón-Montalván, E. A., & Leeson, A. (2024). Bayesian hierarchical model for bias-correcting climate models. Geoscientific Model Development, 17(14), 5733-5757. https://doi.org/10.5194/gmd-17-5733-2024

Vancouver

Carter J, Chacón-Montalván EA, Leeson A. Bayesian hierarchical model for bias-correcting climate models. Geoscientific Model Development. 2024 Jul 31;17(14):5733-5757. doi: 10.5194/gmd-17-5733-2024

Author

Carter, Jeremy ; Chacón-Montalván, Erick A. ; Leeson, Amber. / Bayesian hierarchical model for bias-correcting climate models. In: Geoscientific Model Development. 2024 ; Vol. 17, No. 14. pp. 5733-5757.

Bibtex

@article{686b8913c62d4b47b49ebd6458dab378,
title = "Bayesian hierarchical model for bias-correcting climate models",
abstract = "Climate models, derived from process understanding, are essential tools in the study of climate change and its wide-ranging impacts. Hindcast and future simulations provide comprehensive spatiotemporal estimates of climatology that are frequently employed within the environmental sciences community, although the output can be afflicted with bias that impedes direct interpretation. Post-processing bias correction approaches utilise observational data to address this challenge, although they are typically criticised for not being physically justified and not considering uncertainty in the correction. This paper proposes a novel Bayesian bias correction framework that robustly propagates uncertainty and models underlying spatial covariance patterns. Shared latent Gaussian processes are assumed between the in situ observations and climate model output, with the aim of partially preserving the covariance structure from the climate model after bias correction, which is based on well-established physical laws. Results demonstrate added value in modelling shared generating processes under several simulated scenarios, with the most value added for the case of sparse in situ observations and smooth underlying bias. Additionally, the propagation of uncertainty to a simulated final bias-corrected time series is illustrated, which is of key importance to a range of stakeholders, such as climate scientists engaged in impact studies, decision-makers trying to understand the likelihood of particular scenarios and individuals involved in climate change adaption strategies where accurate risk assessment is required for optimal resource allocation. This paper focuses on one-dimensional simulated examples for clarity, although the code implementation is developed to also work on multi-dimensional input data, encouraging follow-on real-world application studies that will further validate performance and remaining limitations. The Bayesian framework supports uncertainty propagation under model adaptations required for specific applications, providing a flexible approach that increases the scope of data assimilation tasks more generally.",
author = "Jeremy Carter and Chac{\'o}n-Montalv{\'a}n, {Erick A.} and Amber Leeson",
year = "2024",
month = jul,
day = "31",
doi = "10.5194/gmd-17-5733-2024",
language = "English",
volume = "17",
pages = "5733--5757",
journal = "Geoscientific Model Development",
issn = "1991-959X",
publisher = "Copernicus Gesellschaft mbH",
number = "14",

}

RIS

TY - JOUR

T1 - Bayesian hierarchical model for bias-correcting climate models

AU - Carter, Jeremy

AU - Chacón-Montalván, Erick A.

AU - Leeson, Amber

PY - 2024/7/31

Y1 - 2024/7/31

N2 - Climate models, derived from process understanding, are essential tools in the study of climate change and its wide-ranging impacts. Hindcast and future simulations provide comprehensive spatiotemporal estimates of climatology that are frequently employed within the environmental sciences community, although the output can be afflicted with bias that impedes direct interpretation. Post-processing bias correction approaches utilise observational data to address this challenge, although they are typically criticised for not being physically justified and not considering uncertainty in the correction. This paper proposes a novel Bayesian bias correction framework that robustly propagates uncertainty and models underlying spatial covariance patterns. Shared latent Gaussian processes are assumed between the in situ observations and climate model output, with the aim of partially preserving the covariance structure from the climate model after bias correction, which is based on well-established physical laws. Results demonstrate added value in modelling shared generating processes under several simulated scenarios, with the most value added for the case of sparse in situ observations and smooth underlying bias. Additionally, the propagation of uncertainty to a simulated final bias-corrected time series is illustrated, which is of key importance to a range of stakeholders, such as climate scientists engaged in impact studies, decision-makers trying to understand the likelihood of particular scenarios and individuals involved in climate change adaption strategies where accurate risk assessment is required for optimal resource allocation. This paper focuses on one-dimensional simulated examples for clarity, although the code implementation is developed to also work on multi-dimensional input data, encouraging follow-on real-world application studies that will further validate performance and remaining limitations. The Bayesian framework supports uncertainty propagation under model adaptations required for specific applications, providing a flexible approach that increases the scope of data assimilation tasks more generally.

AB - Climate models, derived from process understanding, are essential tools in the study of climate change and its wide-ranging impacts. Hindcast and future simulations provide comprehensive spatiotemporal estimates of climatology that are frequently employed within the environmental sciences community, although the output can be afflicted with bias that impedes direct interpretation. Post-processing bias correction approaches utilise observational data to address this challenge, although they are typically criticised for not being physically justified and not considering uncertainty in the correction. This paper proposes a novel Bayesian bias correction framework that robustly propagates uncertainty and models underlying spatial covariance patterns. Shared latent Gaussian processes are assumed between the in situ observations and climate model output, with the aim of partially preserving the covariance structure from the climate model after bias correction, which is based on well-established physical laws. Results demonstrate added value in modelling shared generating processes under several simulated scenarios, with the most value added for the case of sparse in situ observations and smooth underlying bias. Additionally, the propagation of uncertainty to a simulated final bias-corrected time series is illustrated, which is of key importance to a range of stakeholders, such as climate scientists engaged in impact studies, decision-makers trying to understand the likelihood of particular scenarios and individuals involved in climate change adaption strategies where accurate risk assessment is required for optimal resource allocation. This paper focuses on one-dimensional simulated examples for clarity, although the code implementation is developed to also work on multi-dimensional input data, encouraging follow-on real-world application studies that will further validate performance and remaining limitations. The Bayesian framework supports uncertainty propagation under model adaptations required for specific applications, providing a flexible approach that increases the scope of data assimilation tasks more generally.

U2 - 10.5194/gmd-17-5733-2024

DO - 10.5194/gmd-17-5733-2024

M3 - Journal article

VL - 17

SP - 5733

EP - 5757

JO - Geoscientific Model Development

JF - Geoscientific Model Development

SN - 1991-959X

IS - 14

ER -