Nonlinear stochastic modelling with Langevin regression

Callaham, Jared; Loiseau, Jean-Christophe; Rigas, Georgios; Brunton, Steven L.

doi:10.1098/rspa.2021.0092

Cited by 46 publications

(43 citation statements)

References 83 publications

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“…It is also possible to combine SINDy with deep autoencoders to identify a coordinate system in which the dynamics are approximately sparse [119]. Other extensions include the discovery partial differential equations [123,124], the modeling of stochastic dynamics [125][126][127], and weak formulations of the problem [128][129][130], among others [124,[131][132][133]. SINDy has also been extended to accommodate tensor libraries, which dramatically increases its ability to handle systems with high state dimension [134].…”

Section: Sparse Identification Of Nonlinear Dynamicsmentioning

confidence: 99%

Deeptime: a Python library for machine learning dynamical models from time series data

Hoffmann

Scherer

Hempel

et al. 2021

Mach. Learn.: Sci. Technol.

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Generation and analysis of time-series data is relevant to many quantitative fields ranging from economics to fluid mechanics. In the physical sciences, structures such as metastable and coherent sets, slow relaxation processes, collective variables, dominant transition pathways or manifolds and channels of probability flow can be of great importance for understanding and characterizing the kinetic, thermodynamic and mechanistic properties of the system. Deeptime is a general purpose Python library offering various tools to estimate dynamical models based on time-series data including conventional linear learning methods, such as Markov state models (MSMs), Hidden Markov Models and Koopman models, as well as kernel and deep learning approaches such as VAMPnets and deep MSMs. The library is largely compatible with scikit-learn, having a range of Estimator classes for these different models, but in contrast to scikit-learn also provides deep Model classes, e.g. in the case of an MSM, which provide a multitude of analysis methods to compute interesting thermodynamic, kinetic and dynamical quantities, such as free energies, relaxation times and transition paths. The library is designed for ease of use but also easily maintainable and extensible code. In this paper we introduce the main features and structure of the deeptime software. Deeptime can be found under https://deeptime-ml.github.io/.

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Section: Sparse Identification Of Nonlinear Dynamicsmentioning

confidence: 99%

Deeptime: a Python library for machine learning dynamical models from time series data

Hoffmann

Scherer

Hempel

et al. 2021

Mach. Learn.: Sci. Technol.

View full text Add to dashboard Cite

show abstract

“…In particular [6] used a robust method termed SR3 (sparse relaxed regularized regression) to extract the sparse, nonzero coefficients of the dynamical model. Since its introduction, SINDy has been applied to a wide range of systems, including for reduced-order models of fluid dynamics [7]- [14] and plasma dynamics [15], [16], turbulence closures [17]- [19], nonlinear optics [20], numerical integration schemes [21], discrepancy modeling [22], [23], boundary value problems [24], multiscale dynamics [25], identifying dynamics on Poincare maps [26], [27], tensor formulations [28], and systems with stochastic dynamics [29], [30]. It can also be used to jointly discovery coordinates and dynamics simultaneously [31], [32].…”

Section: Introductionmentioning

confidence: 99%

A Toolkit for Data-Driven Discovery of Governing Equations in High-Noise Regimes

Delahunt

Kutz

2022

IEEE Access

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We consider the data-driven discovery of governing equations from time-series data in the limit of high noise. The algorithms developed describe an extensive toolkit of methods for circumventing the deleterious effects of noise in the context of the sparse identification of nonlinear dynamics (SINDy) framework. We offer two primary contributions, both focused on noisy data acquired from a system ẋ = f (x). First, we propose, for use in high-noise settings, an extensive toolkit of critically enabling extensions for the SINDy regression method, to progressively cull functionals from an over-complete library and yield a set of sparse equations that regress to the derivate ẋ. This toolkit includes: (regression step) weight timepoints based on estimated noise, use ensembles to estimate coefficients, and regress using FFTs; (culling step) leverage linear dependence of functionals, and restore and protect culled functionals based on Figures of Merit (FoMs). In a novel Assessment step, we define FoMs that compare model predictions to the original time-series (i.e., x(t) rather than ẋ(t)). These innovations can extract sparse governing equations and coefficients from high-noise time-series data (e.g., 300% added noise). For example, it discovers the correct sparse libraries in the Lorenz system, with median coefficient estimate errors equal to 1%−3% (for 50% noise), 6%−8% (for 100% noise); and 23%−25% (for 300% noise). The enabling modules in the toolkit are combined into a single method, but the individual modules can be tactically applied in other equation discovery methods (SINDy or not) to improve results on high-noise data. Second, we propose a technique, applicable to any model discovery method based on ẋ = f (x), to assess the accuracy of a discovered model in the context of non-unique solutions due to noisy data. Currently, this non-uniqueness can obscure a discovered model's accuracy and thus a discovery method's effectiveness. We describe a technique that uses linear dependencies among functionals to transform a discovered model into an equivalent form that is closest to the true model, enabling more accurate assessment of a discovered model's accuracy.

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“…The stochastic framework is not considered in this paper, but its results apply to systems defined by stochastic differential equations as described in [8]. The stochastic setting contains many challenging problems and requires sophisticated tools, based e.g., on the Kolmogorov backward equation [8], the forward and adjoint Fokker-Planck equations [16][17][18], or the Koopman operator fitting [19].…”

Section: Contributions and Organisation Of The Papermentioning

confidence: 99%

Identification of Nonlinear Systems Using the Infinitesimal Generator of the Koopman Semigroup—A Numerical Implementation of the Mauroy–Goncalves Method

Drmač

Mezić

Mohr³

2021

Mathematics

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Inferring the latent structure of complex nonlinear dynamical systems in a data driven setting is a challenging mathematical problem with an ever increasing spectrum of applications in sciences and engineering. Koopman operator-based linearization provides a powerful framework that is suitable for identification of nonlinear systems in various scenarios. A recently proposed method by Mauroy and Goncalves is based on lifting the data snapshots into a suitable finite dimensional function space and identification of the infinitesimal generator of the Koopman semigroup. This elegant and mathematically appealing approach has good analytical (convergence) properties, but numerical experiments show that software implementation of the method has certain limitations. More precisely, with the increased dimension that guarantees theoretically better approximation and ultimate convergence, the numerical implementation may become unstable and it may even break down. The main sources of numerical difficulties are the computations of the matrix representation of the compressed Koopman operator and its logarithm. This paper addresses the subtle numerical details and proposes a new implementation algorithm that alleviates these problems.

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Nonlinear stochastic modelling with Langevin regression

Cited by 46 publications

References 83 publications

Deeptime: a Python library for machine learning dynamical models from time series data

Deeptime: a Python library for machine learning dynamical models from time series data

A Toolkit for Data-Driven Discovery of Governing Equations in High-Noise Regimes

Identification of Nonlinear Systems Using the Infinitesimal Generator of the Koopman Semigroup—A Numerical Implementation of the Mauroy–Goncalves Method

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