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Automatically discovering ordinary differential equations from data with sparse regression

Kevin J. Egan, Weizhen Li, Rui Carvalho

2024Communications Physics32 citationsDOIOpen Access PDF

Abstract

Abstract Discovering nonlinear differential equations that describe system dynamics from empirical data is a fundamental challenge in contemporary science. While current methods can identify such equations, they often require extensive manual hyperparameter tuning, limiting their applicability. Here, we propose a methodology to identify dynamical laws by integrating denoising techniques to smooth the signal, sparse regression to identify the relevant parameters, and bootstrap confidence intervals to quantify the uncertainty of the estimates. We evaluate our method on well-known ordinary differential equations with an ensemble of random initial conditions, time series of increasing length, and varying signal-to-noise ratios. Our algorithm consistently identifies three-dimensional systems, given moderately-sized time series and high levels of signal quality relative to background noise. By accurately discovering dynamical systems automatically, our methodology has the potential to impact the understanding of complex systems, especially in fields where data are abundant, but developing mathematical models demands considerable effort.

Topics & Concepts

HyperparameterOrdinary differential equationDynamical systems theoryComputer scienceNoise (video)Nonlinear systemDifferential equationSeries (stratigraphy)RegressionMathematicsAlgorithmApplied mathematicsMachine learningArtificial intelligenceStatisticsPaleontologyImage (mathematics)BiologyPhysicsQuantum mechanicsMathematical analysisTime Series Analysis and ForecastingModel Reduction and Neural NetworksNeural dynamics and brain function
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