A new nudging method for data assimilation, delay‐coordinate nudging, is presented. Delay‐coordinate nudging makes explicit use of present and past observations in the formulation of the forcing driving the model evolution at each time step. Numerical experiments with a low‐order chaotic system show that the new method systematically outperforms standard nudging in different model and observational scenarios, also when using an unoptimized formulation of the delay‐nudging coefficients. A connection between the optimal delay and the dominant Lyapunov exponent of the dynamics is found based on heuristic arguments and is confirmed by the numerical results, providing a guideline for the practical implementation of the algorithm. Delay‐coordinate nudging preserves the easiness of implementation, the intuitive functioning and the reduced computational cost of the standard nudging, making it a potential alternative especially in the field of seasonal‐to‐decadal predictions with large Earth system models that limit the use of more sophisticated data assimilation procedures

A Carrassi

A Dalcher

A Gelb

A. Carrassi

A. Hannart

AT Ihler

C Gini

C Robert

D Kondrashov

DA Stone

E Cosme

EN Lorenz

F Chevallier

G Evensen

J Bhend

J Pearl

J Ruiz

J. Ruiz

K Ide

KE Trenberth

L Bengtsson

L Roques

LE Baum

M Bocquet

M Ghil

M. Bocquet

M. Ghil

M. Pulido

MD Chekroun

MO Lorenz

MR Allen

N Christidis

N Massey

N Wiener

O Talagrand

P Del Moral

P Heidelberg

P Sakov

P Tandeo

P. Naveau

P. Tandeo

PA Stott

PL Houtekamer

RE Kalman

RN Hoffman

TCK Lee

TE Harris

TN Palmer

Climatic Change

English

arXiv

International audienceWe describe a new approach that allows for systematic causal attribution of weather and climate-related events, in near-real time. The method is designed so as to facilitate its implementation at meteorological centers by relying on data and methods that are routinely available when numerically forecasting the weather. We thus show that causal attribution can be obtained as a by-product of data assimilation procedures run on a daily basis to update numerical weather prediction (NWP) models with new atmospheric observations; hence, the proposed methodology can take advantage of the powerful computational and observational capacity of weather forecasting centers. We explain the theoretical rationale of this approach and sketch the most prominent features of a "data assimilation-based detection and attribution" (DADA) procedure. The proposal is illustrated in the context of the classical three-variable Lorenz model with additional forcing. The paper concludes by raising several theoretical and practical questions that need to be addressed to make the proposal operational within NWP centers

Hannart, Alexis

Carrassi, Alberto

Bocquet, Marc

Ghil, Michael

Naveau, Philippe

Pulido, Manuel

Ruiz, Juan

Tandeo, Pierre

HAL-Ecole des Ponts ParisTech

DADA: Data Assimilation for the Detection and Attribution of weather- and climate-related events

We describe a new approach that allows for systematic causal attribution of weather and climate-related events, in near-real time. The method is designed so as to facilitate its implementation at meteorological centers by relying on data and methods that are routinely available when numerically forecasting the weather. We thus show that causal attribution can be obtained as a by-product of data assimilation procedures run on a daily basis to update numerical weather prediction (NWP) models with new atmospheric observations; hence, the proposed methodology can take advantage of the powerful computational and observational capacity of weather forecasting centers. We explain the theoretical rationale of this approach and sketch the most prominent features of a “data assimilation–based detection and attribution” (DADA) procedure. The proposal is illustrated in the context of the classical three-variable Lorenz model with additional forcing. The paper concludes by raising several theoretical and practical questions that need to be addressed to make the proposal operational within NWP centers.Fil: Hannart, Alexis. Consejo Nacional de Investigaciones Científicas y Técnicas. Oficina de Coordinación Administrativa Ciudad Universitaria. Centro de Investigaciones del Mar y la Atmosfera. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales. Centro de Investigaciones del Mar y la Atmosfera; ArgentinaFil: Carrasi, A.. Mohn-Sverdrup Center; NoruegaFil: Bocquet, M.. Université Paris-Est; FranciaFil: Ghil, M.. Ecole Normale Supérieure; Francia. University of California at Los Angeles; Estados UnidosFil: Naveau, P.. Centre National de la Recherche Scientifique; FranciaFil: Pulido, M.. Universidad Nacional del Nordeste; ArgentinaFil: Ruiz, Juan Jose. Consejo Nacional de Investigaciones Científicas y Técnicas. Oficina de Coordinación Administrativa Ciudad Universitaria. Centro de Investigaciones del Mar y la Atmosfera. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales. Centro de Investigaciones del Mar y la Atmosfera; ArgentinaFil: Tandeo, P.. Télécom Bretagne; Franci

Carrasi, A.

Bocquet, M.

Ghil, M.

Naveau, P.

Pulido, M.

Ruiz, Juan Jose

Tandeo, P.

CONICET Digital

DADA: data assimilation for the detection and attribution of weather and climate-related events

HAL-Université de Bretagne Occidentale

HAL-INSU

HAL UVSQ

LAReferencia - Red Federada de Repositorios Institucionales de Publicaciones Científicas Latinoamericanas

Hannart, A.

Carrassi, A.

Ruiz, J.

Central Archive at the University of Reading

DADA: data assimilation for the detection and attribution of weather and climate-related events

Abstract

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