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Recurrent flow patterns as a basis for two-dimensional turbulence: Predicting statistics from structures

Jacob Page, Peter Nørgaard, Michael P. Brenner, Rich R. Kerswell

2024Proceedings of the National Academy of Sciences27 citationsDOIOpen Access PDF

Abstract

, 303 (1948)]. The chaotic dynamics are shaped by the unstable simple invariant solutions populating the inertial manifold. The hope has been to turn this picture into a predictive framework where the statistics of the flow follow from a weighted sum of the statistics of each simple invariant solution. Two outstanding obstacles have prevented this goal from being achieved: 1) paucity of known solutions and 2) the lack of a rational theory for predicting the required weights. Here, we describe a method to substantially solve these problems, and thereby provide compelling evidence that the probability density functions (PDFs) of a fully developed turbulent flow can be reconstructed with a set of unstable periodic orbits. Our method for finding solutions uses automatic differentiation, with high-quality guesses constructed by minimizing a trajectory-dependent loss function. We use this approach to find hundreds of solutions in turbulent, two-dimensional Kolmogorov flow. Robust statistical predictions are then computed by learning weights after converting a turbulent trajectory into a Markov chain for which the states are individual solutions, and the nearest solution to a given snapshot is determined using a deep convolutional autoencoder. In this study, the PDFs of a spatiotemporally chaotic system have been successfully reproduced with a set of simple invariant states, and we provide a fascinating connection between self-sustaining dynamical processes and the more well-known statistical properties of turbulence.

Topics & Concepts

TurbulenceInvariant (physics)Dynamical systems theoryStatistical physicsChaoticProbability density functionFlow (mathematics)Markov chainMathematicsApplied mathematicsComputer scienceArtificial intelligencePhysicsStatisticsGeometryQuantum mechanicsThermodynamicsMathematical physicsModel Reduction and Neural NetworksProbabilistic and Robust Engineering DesignGaussian Processes and Bayesian Inference
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