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Gaussian processes meet NeuralODEs: a Bayesian framework for learning the dynamics of partially observed systems from scarce and noisy data

Mohamed Aziz Bhouri, Paris Perdikaris

2022Philosophical Transactions of the Royal Society A Mathematical Physical and Engineering Sciences24 citationsDOIOpen Access PDF

Abstract

We present a machine learning framework (GP-NODE) for Bayesian model discovery from partial, noisy and irregular observations of nonlinear dynamical systems. The proposed method takes advantage of differentiable programming to propagate gradient information through ordinary differential equation solvers and perform Bayesian inference with respect to unknown model parameters using Hamiltonian Monte Carlo sampling and Gaussian Process priors over the observed system states. This allows us to exploit temporal correlations in the observed data, and efficiently infer posterior distributions over plausible models with quantified uncertainty. The use of the Finnish Horseshoe as a sparsity-promoting prior for free model parameters also enables the discovery of parsimonious representations for the latent dynamics. A series of numerical studies is presented to demonstrate the effectiveness of the proposed GP-NODE method including predator-prey systems, systems biology and a 50-dimensional human motion dynamical system. This article is part of the theme issue 'Data-driven prediction in dynamical systems'.

Topics & Concepts

Computer scienceDynamical systems theoryGaussian processBayesian inferenceBayesian probabilityArtificial intelligenceUncertainty quantificationOrdinary differential equationMachine learningAlgorithmGaussianMathematicsDifferential equationPhysicsMathematical analysisQuantum mechanicsModel Reduction and Neural NetworksGaussian Processes and Bayesian InferenceControl Systems and Identification
Gaussian processes meet NeuralODEs: a Bayesian framework for learning the dynamics of partially observed systems from scarce and noisy data | Litcius