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Sparsifying priors for Bayesian uncertainty quantification in model discovery.

Seth M Hirsh1, David A Barajas-Solano2, J Nathan Kutz3

  • 1Department of Physics, University of Washington, Seattle, WA, USA.

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|February 28, 2022
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Summary
This summary is machine-generated.

We introduce Uncertainty Quantification SINDy (UQ-SINDy), a probabilistic method for discovering governing equations from data. UQ-SINDy enhances model interpretability and accuracy, even with limited or noisy data.

Keywords:
Bayesian inferencemodel discoveryuncertainty quantification

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Area of Science:

  • Dynamical Systems and Control Theory
  • Machine Learning and Artificial Intelligence
  • Scientific Computing

Background:

  • Discovering governing equations from observational data is crucial for scientific understanding and prediction.
  • Existing methods like Sparse Identification of Nonlinear Dynamics (SINDy) offer interpretability but can be sensitive to noise and data limitations.
  • Quantifying uncertainty in discovered models is essential for reliable real-world applications.

Purpose of the Study:

  • To develop a probabilistic model discovery method for identifying ordinary differential equations from multivariate data.
  • To introduce Uncertainty Quantification SINDy (UQ-SINDy) that quantifies coefficient and model uncertainty.
  • To enhance robustness, interpretability, and generalization capabilities of discovered dynamical models.

Main Methods:

  • Leveraging the Sparse Identification of Nonlinear Dynamics (SINDy) framework.
  • Employing sparse Bayesian inference for estimating SINDy coefficients, incorporating uncertainty quantification.
  • Utilizing Markov chain Monte Carlo with spike and slab and regularized horseshoe priors for sparse inference.

Main Results:

  • UQ-SINDy effectively quantifies uncertainty in SINDy coefficients and candidate function inclusion probabilities.
  • The method demonstrates robustness against observation noise and requires significantly less data compared to existing techniques.
  • Accurate dynamical models were discovered even with orders-of-magnitude less data and in the presence of noise.

Conclusions:

  • UQ-SINDy provides a transformative approach to model discovery, offering enhanced interpretability and generalization.
  • The probabilistic framework makes it suitable for real-world applications with limited and noisy observational data.
  • This method advances the field of automated scientific discovery by incorporating rigorous uncertainty quantification.