Litcius/Paper detail

Hierarchical deep learning of multiscale differential equation time-steppers

Yuying Liu, J. Nathan Kutz, Steven L. Brunton

2022Philosophical Transactions of the Royal Society A Mathematical Physical and Engineering Sciences45 citationsDOIOpen Access PDF

Abstract

Nonlinear differential equations rarely admit closed-form solutions, thus requiring numerical time-stepping algorithms to approximate solutions. Further, many systems characterized by multiscale physics exhibit dynamics over a vast range of timescales, making numerical integration expensive. In this work, we develop a hierarchy of deep neural network time-steppers to approximate the dynamical system flow map over a range of time-scales. The model is purely data-driven, enabling accurate and efficient numerical integration and forecasting. Similar ideas can be used to couple neural network-based models with classical numerical time-steppers. Our hierarchical time-stepping scheme provides advantages over current time-stepping algorithms, including (i) capturing a range of timescales, (ii) improved accuracy in comparison with leading neural network architectures, (iii) efficiency in long-time forecasting due to explicit training of slow time-scale dynamics, and (iv) a flexible framework that is parallelizable and may be integrated with standard numerical time-stepping algorithms. The method is demonstrated on numerous nonlinear dynamical systems, including the Van der Pol oscillator, the Lorenz system, the Kuramoto-Sivashinsky equation, and fluid flow pass a cylinder; audio and video signals are also explored. On the sequence generation examples, we benchmark our algorithm against state-of-the-art methods, such as LSTM, reservoir computing and clockwork RNN. This article is part of the theme issue 'Data-driven prediction in dynamical systems'.

Topics & Concepts

Computer scienceDynamical systems theoryNonlinear systemArtificial neural networkLorenz systemBenchmark (surveying)AlgorithmDeep learningRange (aeronautics)Dynamical system (definition)Flow (mathematics)Applied mathematicsArtificial intelligenceMathematicsPhysicsQuantum mechanicsMaterials scienceGeographyChaoticComposite materialGeometryGeodesyModel Reduction and Neural NetworksMeteorological Phenomena and SimulationsFluid Dynamics and Turbulent Flows