Gaussian-process emulation for integrating data-driven aerosol-cloud physics from simulation, satellite, and ground-based data

F. Glassmeier; Fabian Hoffmann; Graham Feingold; Edward Gryspeerdt; J.A. van Hooft; Takanobu Yamaguchi; Jill S. Johnson; Ken S. Carslaw

doi:10.5194/ems2022-701

Gaussian-process emulation for integrating data-driven aerosol-cloud physics from simulation, satellite, and ground-based data

F. Glassmeier, Fabian Hoffmann, Graham Feingold, Edward Gryspeerdt, J.A. van Hooft, Takanobu Yamaguchi, Jill S. Johnson, Ken S. Carslaw

Atmospheric Remote Sensing

Research output: Chapter in Book/Conference proceedings/Edited volume › Conference contribution › Scientific › peer-review

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Abstract

Data-driven quantification and parameterization of cloud physics in general, and of aerosol-cloud interactions in particular, rely on input data from observations or detailed simulations. These data sources have complementary limitations in terms of their spatial and temporal coverage and resolution; simulation data has the advantage of readily providing causality but cannot represent the full process complexity. In order to base data-driven approaches on comprehensive information, we therefore need ways to integrate different data sources.

We discuss how the classical statistical technique of Gaussian-process emulation can be combined with specifically initialized ensembles of detailed cloud simulations (large-eddy simulations, LES) to provide a framework for evaluating data-driven descriptions of cloud characteristics and processes across different data sources. We specifically illustrate this approach for integrating LES and satellite data of aerosol-cloud interactions in subtropical stratocumulus cloud decks. We furthermore explore the extension of our framework to ground-based observations of Arctic mixed-phase clouds.

Original language	English
Title of host publication	EMS Annual Meeting Abstracts
Number of pages	1
DOIs	https://doi.org/10.5194/ems2022-701
Publication status	Published - 2022
Event	EMS Annual Meeting 2022 - Bonn, Germany Duration: 4 Sept 2022 → 9 Sept 2022

Publication series

Name	EMS Annual Meeting Abstracts
Number	EMS2022-701
Volume	19

Conference

Conference	EMS Annual Meeting 2022
Country/Territory	Germany
City	Bonn
Period	4/09/22 → 9/09/22

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10.5194/ems2022-701

EMS2022-701-printFinal published version, 102 KBLicence: CC BY

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Glassmeier, F., Hoffmann, F., Feingold, G., Gryspeerdt, E., van Hooft, J. A., Yamaguchi, T., Johnson, J. S., & Carslaw, K. S. (2022). Gaussian-process emulation for integrating data-driven aerosol-cloud physics from simulation, satellite, and ground-based data. In EMS Annual Meeting Abstracts Article EMS2022-701 (EMS Annual Meeting Abstracts; Vol. 19, No. EMS2022-701). https://doi.org/10.5194/ems2022-701

@inproceedings{5550c9bc5eca4945a0842eeebcfbb4fe,

title = "Gaussian-process emulation for integrating data-driven aerosol-cloud physics from simulation, satellite, and ground-based data",

abstract = "Data-driven quantification and parameterization of cloud physics in general, and of aerosol-cloud interactions in particular, rely on input data from observations or detailed simulations. These data sources have complementary limitations in terms of their spatial and temporal coverage and resolution; simulation data has the advantage of readily providing causality but cannot represent the full process complexity. In order to base data-driven approaches on comprehensive information, we therefore need ways to integrate different data sources. We discuss how the classical statistical technique of Gaussian-process emulation can be combined with specifically initialized ensembles of detailed cloud simulations (large-eddy simulations, LES) to provide a framework for evaluating data-driven descriptions of cloud characteristics and processes across different data sources. We specifically illustrate this approach for integrating LES and satellite data of aerosol-cloud interactions in subtropical stratocumulus cloud decks. We furthermore explore the extension of our framework to ground-based observations of Arctic mixed-phase clouds.",

author = "F. Glassmeier and Fabian Hoffmann and Graham Feingold and Edward Gryspeerdt and {van Hooft}, J.A. and Takanobu Yamaguchi and Johnson, {Jill S.} and Carslaw, {Ken S.}",

year = "2022",

doi = "10.5194/ems2022-701",

language = "English",

series = "EMS Annual Meeting Abstracts",

number = "EMS2022-701",

booktitle = "EMS Annual Meeting Abstracts",

note = "EMS Annual Meeting 2022 ; Conference date: 04-09-2022 Through 09-09-2022",

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Glassmeier, F, Hoffmann, F, Feingold, G, Gryspeerdt, E, van Hooft, JA, Yamaguchi, T, Johnson, JS & Carslaw, KS 2022, Gaussian-process emulation for integrating data-driven aerosol-cloud physics from simulation, satellite, and ground-based data. in EMS Annual Meeting Abstracts., EMS2022-701, EMS Annual Meeting Abstracts, no. EMS2022-701, vol. 19, EMS Annual Meeting 2022, Bonn, Germany, 4/09/22. https://doi.org/10.5194/ems2022-701

Gaussian-process emulation for integrating data-driven aerosol-cloud physics from simulation, satellite, and ground-based data. / Glassmeier, F.; Hoffmann, Fabian; Feingold, Graham et al.
EMS Annual Meeting Abstracts. 2022. EMS2022-701 (EMS Annual Meeting Abstracts; Vol. 19, No. EMS2022-701).

Research output: Chapter in Book/Conference proceedings/Edited volume › Conference contribution › Scientific › peer-review

TY - GEN

T1 - Gaussian-process emulation for integrating data-driven aerosol-cloud physics from simulation, satellite, and ground-based data

AU - Glassmeier, F.

AU - Hoffmann, Fabian

AU - Feingold, Graham

AU - Gryspeerdt, Edward

AU - van Hooft, J.A.

AU - Yamaguchi, Takanobu

AU - Johnson, Jill S.

AU - Carslaw, Ken S.

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N2 - Data-driven quantification and parameterization of cloud physics in general, and of aerosol-cloud interactions in particular, rely on input data from observations or detailed simulations. These data sources have complementary limitations in terms of their spatial and temporal coverage and resolution; simulation data has the advantage of readily providing causality but cannot represent the full process complexity. In order to base data-driven approaches on comprehensive information, we therefore need ways to integrate different data sources. We discuss how the classical statistical technique of Gaussian-process emulation can be combined with specifically initialized ensembles of detailed cloud simulations (large-eddy simulations, LES) to provide a framework for evaluating data-driven descriptions of cloud characteristics and processes across different data sources. We specifically illustrate this approach for integrating LES and satellite data of aerosol-cloud interactions in subtropical stratocumulus cloud decks. We furthermore explore the extension of our framework to ground-based observations of Arctic mixed-phase clouds.

AB - Data-driven quantification and parameterization of cloud physics in general, and of aerosol-cloud interactions in particular, rely on input data from observations or detailed simulations. These data sources have complementary limitations in terms of their spatial and temporal coverage and resolution; simulation data has the advantage of readily providing causality but cannot represent the full process complexity. In order to base data-driven approaches on comprehensive information, we therefore need ways to integrate different data sources. We discuss how the classical statistical technique of Gaussian-process emulation can be combined with specifically initialized ensembles of detailed cloud simulations (large-eddy simulations, LES) to provide a framework for evaluating data-driven descriptions of cloud characteristics and processes across different data sources. We specifically illustrate this approach for integrating LES and satellite data of aerosol-cloud interactions in subtropical stratocumulus cloud decks. We furthermore explore the extension of our framework to ground-based observations of Arctic mixed-phase clouds.

U2 - 10.5194/ems2022-701

DO - 10.5194/ems2022-701

M3 - Conference contribution

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BT - EMS Annual Meeting Abstracts

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Y2 - 4 September 2022 through 9 September 2022

ER -

Gaussian-process emulation for integrating data-driven aerosol-cloud physics from simulation, satellite, and ground-based data

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