Learning dynamical systems from data: A simple cross-validation perspective, part I: Parametric kernel flows

Hamzi, Boumediene; Owhadi, Houman

doi:10.1016/j.physd.2020.132817

Cited by 65 publications

(46 citation statements)

References 31 publications

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“…A reminder on kernel methods for regularly sampled time series. The simplest approach to forecasting the time series (employed in [22]) is to assume that x 1 , x 2 , . .…”

Section: 2mentioning

confidence: 99%

“…, x k−τ † +1 ) to predict future state. Given τ ∈ N * (see [22] for how τ can be learned in practice), the approximation of the dynamical system can then be recast as that of interpolating f † from pointwise measurements…”

Section: 2mentioning

confidence: 99%

“…Yet, the accuracy of these emulators depends on the kernel, and the problem of selecting a good kernel has received less attention. Recently, the experiments by Hamzi and Owhadi [22] show that when the time series is regularly sampled, Kernel Flows (KF) [34] (an RKHS technique) can successfully reconstruct the dynamics of some prototypical chaotic dynamical systems. KFs have subsequently been applied to complex large-scale systems, including climate data [30,41].…”

Section: Introductionmentioning

confidence: 99%

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Learning dynamical systems from data: A simple cross-validation perspective, part III: Irregularly-Sampled Time Series

Lee¹,

Brouwer²,

Hamzi³

et al. 2021

Preprint

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A simple and interpretable way to learn a dynamical system from data is to interpolate its vector-field with a kernel. In particular, this strategy is highly efficient (both in terms of accuracy and complexity) when the kernel is data-adapted using Kernel Flows (KF) [34] (which uses gradient-based optimization to learn a kernel based on the premise that a kernel is good if there is no significant loss in accuracy if half of the data is used for interpolation). Despite its previous successes, this strategy (based on interpolating the vector field driving the dynamical system) breaks down when the observed time series is not regularly sampled in time. In this work, we propose to address this problem by directly approximating the vector field of the dynamical system by incorporating time differences between observations in the (KF) data-adapted kernels. We compare our approach with the classical one over different benchmark dynamical systems and show that it significantly improves the forecasting accuracy while remaining simple, fast, and robust.

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“…A reminder on kernel methods for regularly sampled time series. The simplest approach to forecasting the time series (employed in [22]) is to assume that x 1 , x 2 , . .…”

Section: 2mentioning

confidence: 99%

Section: 2mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Learning dynamical systems from data: A simple cross-validation perspective, part III: Irregularly-Sampled Time Series

Lee¹,

Brouwer²,

Hamzi³

et al. 2021

Preprint

Self Cite

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“…The paper will demonstrate also the generalization capabilities of InceptionTime deep Convolutional Neural Networks (CNN) that would allow the cartographic study of analogous albeit not identical dynamical systems. A review of recent machine learning (ML) methods used in dynamical astronomy can be found in 1 , while some advanced techniques to learn dynamical systems can be found in 2 . Our work differentiates from the recent literature on ML for dynamical systems and dynamical astronomy in that we provide some evidence of the ability of DL at classifying types of motion from dynamic indicators associated to time series.…”

Section: Introductionmentioning

confidence: 99%

Classification of regular and chaotic motions in Hamiltonian systems with deep learning

Celletti

Galeş

Rodríguez-Fernández

et al. 2022

Sci Rep

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This paper demonstrates the capabilities of convolutional neural networks (CNNs) at classifying types of motion starting from time series, without any prior knowledge of the underlying dynamics. The paper applies different forms of deep learning to problems of increasing complexity with the goal of testing the ability of different deep learning architectures at predicting the character of the dynamics by simply observing a time-ordered set of data. We will demonstrate that a properly trained CNN can correctly classify the types of motion on a given data set. We also demonstrate effective generalisation capabilities by using a CNN trained on one dynamic model to predict the character of the motion governed by another dynamic model. The ability to predict types of motion from observations is then verified on a model problem known as the forced pendulum and on a relevant problem in Celestial Mechanics where observational data can be used to predict the long-term evolution of the system.

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“…Despite current success of these methods, tackling high-dimensional nonlinear dynamics is still a challenge. This is, because neural networks require an abundance of parameters whose estimation is costly (e.g., due to a non-convex optimization problem), kernel-based methods require a suitable choice of the kernel [HO20], regression methods need the right choice of transformations, making a suitable basis desirable (for instance by restricting the parametrization to collective variables or reaction coordinates [BKK + 17]), and can result in ill-conditioned problems [FWM10]. Lastly, probabilistic models are more stable and do not require strong intuition about the problem, however often suffer from the curse of dimensionality.…”

Section: Introductionmentioning

confidence: 99%

Data-driven modelling of nonlinear dynamics by barycentric coordinates and memory

Wulkow¹,

Koltai²,

Sunkara³

et al. 2021

Preprint

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We present a numerical method to model dynamical systems from data. We use the recently introduced method Scalable Probabilistic Approximation (SPA) to project points from a Euclidean space to convex polytopes and represent these projected states of a system in new, lower-dimensional coordinates denoting their position in the polytope. We then introduce a specific nonlinear transformation to construct a model of the dynamics in the polytope and to transform back into the original state space. To overcome the potential loss of information from the projection to a lower-dimensional polytope, we use memory in the sense of the delayembedding theorem of Takens. By construction, our method produces stable models. We illustrate the capacity of the method to reproduce even chaotic dynamics and attractors with multiple connected components on various examples.

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Learning dynamical systems from data: A simple cross-validation perspective, part I: Parametric kernel flows

Cited by 65 publications

References 31 publications

Learning dynamical systems from data: A simple cross-validation perspective, part III: Irregularly-Sampled Time Series

Learning dynamical systems from data: A simple cross-validation perspective, part III: Irregularly-Sampled Time Series

Classification of regular and chaotic motions in Hamiltonian systems with deep learning

Data-driven modelling of nonlinear dynamics by barycentric coordinates and memory

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