Fast dimension-reduced climate model calibration and the effect of data aggregation

How will the climate system respond to anthropogenic forcings? One approach to this question relies on climate model projections. Current climate projections are considerably uncertain. Characterizing and, if possible, reducing this uncertainty is an area of ongoing research. We consider the problem...

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Published in:	The Annals of Applied Statistics
Main Authors:	Chang, Won, Haran, Murali, Olson, Roman, Keller, Klaus
Format:	Text
Language:	English
Published:	The Institute of Mathematical Statistics 2014
Subjects:	Climate model calibration Gaussian process principal components high-dimensional spatial data North Atlantic
Online Access:	http://projecteuclid.org/euclid.aoas/1404229509 https://doi.org/10.1214/14-AOAS733

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spelling	ftculeuclid:oai:CULeuclid:euclid.aoas/1404229509 2023-05-15T17:34:28+02:00 Fast dimension-reduced climate model calibration and the effect of data aggregation Chang, Won Haran, Murali Olson, Roman Keller, Klaus 2014-06 application/pdf http://projecteuclid.org/euclid.aoas/1404229509 https://doi.org/10.1214/14-AOAS733 en eng The Institute of Mathematical Statistics 1932-6157 1941-7330 Copyright 2014 Institute of Mathematical Statistics Climate model calibration Gaussian process principal components high-dimensional spatial data Text 2014 ftculeuclid https://doi.org/10.1214/14-AOAS733 2018-10-06T12:47:23Z How will the climate system respond to anthropogenic forcings? One approach to this question relies on climate model projections. Current climate projections are considerably uncertain. Characterizing and, if possible, reducing this uncertainty is an area of ongoing research. We consider the problem of making projections of the North Atlantic meridional overturning circulation (AMOC). Uncertainties about climate model parameters play a key role in uncertainties in AMOC projections. When the observational data and the climate model output are high-dimensional spatial data sets, the data are typically aggregated due to computational constraints. The effects of aggregation are unclear because statistically rigorous approaches for model parameter inference have been infeasible for high-resolution data. Here we develop a flexible and computationally efficient approach using principal components and basis expansions to study the effect of spatial data aggregation on parametric and projection uncertainties. Our Bayesian reduced-dimensional calibration approach allows us to study the effect of complicated error structures and data-model discrepancies on our ability to learn about climate model parameters from high-dimensional data. Considering high-dimensional spatial observations reduces the effect of deep uncertainty associated with prior specifications for the data-model discrepancy. Also, using the unaggregated data results in sharper projections based on our climate model. Our computationally efficient approach may be widely applicable to a variety of high-dimensional computer model calibration problems. Text North Atlantic Project Euclid (Cornell University Library) The Annals of Applied Statistics 8 2
institution	Open Polar
collection	Project Euclid (Cornell University Library)
op_collection_id	ftculeuclid
language	English
topic	Climate model calibration Gaussian process principal components high-dimensional spatial data
spellingShingle	Climate model calibration Gaussian process principal components high-dimensional spatial data Chang, Won Haran, Murali Olson, Roman Keller, Klaus Fast dimension-reduced climate model calibration and the effect of data aggregation
topic_facet	Climate model calibration Gaussian process principal components high-dimensional spatial data
description	How will the climate system respond to anthropogenic forcings? One approach to this question relies on climate model projections. Current climate projections are considerably uncertain. Characterizing and, if possible, reducing this uncertainty is an area of ongoing research. We consider the problem of making projections of the North Atlantic meridional overturning circulation (AMOC). Uncertainties about climate model parameters play a key role in uncertainties in AMOC projections. When the observational data and the climate model output are high-dimensional spatial data sets, the data are typically aggregated due to computational constraints. The effects of aggregation are unclear because statistically rigorous approaches for model parameter inference have been infeasible for high-resolution data. Here we develop a flexible and computationally efficient approach using principal components and basis expansions to study the effect of spatial data aggregation on parametric and projection uncertainties. Our Bayesian reduced-dimensional calibration approach allows us to study the effect of complicated error structures and data-model discrepancies on our ability to learn about climate model parameters from high-dimensional data. Considering high-dimensional spatial observations reduces the effect of deep uncertainty associated with prior specifications for the data-model discrepancy. Also, using the unaggregated data results in sharper projections based on our climate model. Our computationally efficient approach may be widely applicable to a variety of high-dimensional computer model calibration problems.
format	Text
author	Chang, Won Haran, Murali Olson, Roman Keller, Klaus
author_facet	Chang, Won Haran, Murali Olson, Roman Keller, Klaus
author_sort	Chang, Won
title	Fast dimension-reduced climate model calibration and the effect of data aggregation
title_short	Fast dimension-reduced climate model calibration and the effect of data aggregation
title_full	Fast dimension-reduced climate model calibration and the effect of data aggregation
title_fullStr	Fast dimension-reduced climate model calibration and the effect of data aggregation
title_full_unstemmed	Fast dimension-reduced climate model calibration and the effect of data aggregation
title_sort	fast dimension-reduced climate model calibration and the effect of data aggregation
publisher	The Institute of Mathematical Statistics
publishDate	2014
url	http://projecteuclid.org/euclid.aoas/1404229509 https://doi.org/10.1214/14-AOAS733
genre	North Atlantic
genre_facet	North Atlantic
op_relation	1932-6157 1941-7330
op_rights	Copyright 2014 Institute of Mathematical Statistics
op_doi	https://doi.org/10.1214/14-AOAS733
container_title	The Annals of Applied Statistics
container_volume	8
container_issue	2
_version_	1766133313130463232

Fast dimension-reduced climate model calibration and the effect of data aggregation

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