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Bayesian inference of chaotic dynamics by merging data assimilation, machine learning and expectation-maximization

Marc Bocquet, Julien Brajard, Alberto Carrassi, Laurent Bertino

2020Foundations of Data Science93 citationsDOIOpen Access PDF

Abstract

The reconstruction from observations of high-dimensional chaotic dynamics such as geophysical flows is hampered by (ⅰ) the partial and noisy observations that can realistically be obtained, (ⅱ) the need to learn from long time series of data, and (ⅲ) the unstable nature of the dynamics. To achieve such inference from the observations over long time series, it has been suggested to combine data assimilation and machine learning in several ways. We show how to unify these approaches from a Bayesian perspective using expectation-maximization and coordinate descents. In doing so, the model, the state trajectory and model error statistics are estimated all together. Implementations and approximations of these methods are discussed. Finally, we numerically and successfully test the approach on two relevant low-order chaotic models with distinct identifiability.

Topics & Concepts

Computer scienceChaoticMachine learningArtificial intelligenceInferenceBayesian probabilityTime seriesBayesian inferenceData assimilationSeries (stratigraphy)TrajectoryAlgorithmPerspective (graphical)Bayesian statisticsStatistical inferenceKey (lock)Ensemble learningDynamics (music)Data miningNoisy dataStatistical hypothesis testingMathematicsState (computer science)Model Reduction and Neural NetworksMeteorological Phenomena and SimulationsQuantum chaos and dynamical systems