Combining data assimilation and machine learning to infer unresolved scale parametrization

Brajard, Julien; Carrassi, Alberto; Bocquet, Marc; Bertino, Laurent

doi:10.1098/rsta.2020.0086

Cited by 100 publications

(79 citation statements)

References 45 publications

(60 reference statements)

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“…A natural idea to overcome these issues is, instead of constructing the surrogate model from scratch, to build a hybrid model using an already existing, knowledge‐based model (Pathak et al ., 2018b; Brajard et al ., 2020b). In fact, this would mean that we would try to correct the error of the knowledge‐based model.…”

Section: Methodological Aspectsmentioning

confidence: 99%

Using machine learning to correct model error in data assimilation and forecast applications

Farchi

Laloyaux

Bonavita

et al. 2021

Quart J Royal Meteoro Soc

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The idea of using machine learning (ML) methods to reconstruct the dynamics of a system is the topic of recent studies in the geosciences, in which the key output is a surrogate model meant to emulate the dynamical model. In order to treat sparse and noisy observations in a rigorous way, ML can be combined with data assimilation (DA). This yields a class of iterative methods in which, at each iteration, a DA step assimilates the observations and alternates with a ML step to learn the underlying dynamics of the DA analysis. In this article, we propose to use this method to correct the error of an existing, knowledge-based model. In practice, the resulting surrogate model is a hybrid model between the original (knowledge-based) model and the ML model. We demonstrate the feasibility of the method numerically using a two-layer, two-dimensional, quasi-geostrophic channel model. Model error is introduced by the means of perturbed parameters. The DA step is performed using the strong-constraint 4D-Var algorithm, while the ML step is performed using deep learning tools. The ML models are able to learn a substantial part of the model error and the resulting hybrid surrogate models produce better short-to mid-range forecasts. Furthermore, using the hybrid surrogate models for DA yields a significantly better analysis than using the original model.

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Section: Methodological Aspectsmentioning

confidence: 99%

Using machine learning to correct model error in data assimilation and forecast applications

Farchi

Laloyaux

Bonavita

et al. 2021

Quart J Royal Meteoro Soc

Self Cite

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“…Regarding the poor concordance between rural observations and the HR ground truth, it suggests the importance of using data assimilation in high-resolution CTMs. On this particular issue, our SRNN models may be used as fast surrogate simulations in a model-based ensemble data assimilation framework [37][38][39]. They can also be extended to a fully NN-based data assimilation scheme, where the end-to-end learning strategy consists in using both the coarse resolution (with the HR covariates) and the observations to feed a neural network whose target is the anomaly between the observations and the coarse resolution [32,40].…”

Section: Resultsmentioning

confidence: 99%

Deep learning techniques applied to super-resolution chemistry transport modeling for operational uses

Bessagnet

Beauchamp

Menut

et al. 2021

Environ. Res. Commun.

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Air quality modeling tools are largely used to assess air pollution mitigation and monitoring strategies. While neural networks (NN) were mostly developed based on observations to derive statistical models at stations, the use of Eulerian chemistry transport models (CTMs) was mainly devoted to air quality predictions over large areas and the evaluation of emission reduction strategies. In this study, we investigate deep learning architectures to create a metamodel of the process oriented CTM CHIMERE and significantly reduce the computing times required for super-resolution simulations. The key point is the selection of input variables and the way to implement them in the NN. We perform a quantitative evaluation of the proposed approaches on a real case-study. The best NN architecture displays very good performances in terms of prediction of pollutant concentrations observed at stations with respect to the raw super-resolution CHIMERE simulation, with a correlation coefficient above 0.95. The best NN is also able to display better performances when compared to observations than the raw high resolution simulation. Currently the model is designed to be used for air quality forecasting and requires improvement for the definition of air quality management strategies.

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“…Our results build on a growing literature describing networks that learn system dynamics (Grzeszczuk et al., 1998; Sanchez‐Gonzalez et al., 2020), arising from ordinary differential equations (Chen et al., 2019; Fablet et al., 2018) and PDEs (Long et al., 2018; Rudy et al., 2019), some of which have applied numerical integration schemes during training (Wang & Lin, 1998). Several studies have used ML to learn parametrizations for L96 (Dueben & Bauer, 2018; Gagne et al., 2020; Watson, 2019) and other Earth science models but have either used offline training or employed Ensemble Kalman filtering and related approaches that do not require derivatives (Brajard et al., 2021; Pawar & San, 2020; Rasp, 2020).…”

Section: Discussionmentioning

confidence: 99%

Deep Emulators for Differentiation, Forecasting, and Parametrization in Earth Science Simulators

Nonnenmacher

Greenberg

2021

J Adv Model Earth Syst

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Combining data assimilation and machine learning to infer unresolved scale parametrization

Cited by 100 publications

References 45 publications

Using machine learning to correct model error in data assimilation and forecast applications

Using machine learning to correct model error in data assimilation and forecast applications

Deep learning techniques applied to super-resolution chemistry transport modeling for operational uses

Deep Emulators for Differentiation, Forecasting, and Parametrization in Earth Science Simulators

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