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Data-driven discovery of Green's functions with human-understandable deep learning.

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Deep learning can accelerate scientific discovery by training rational neural networks to learn physical system properties. This human-machine partnership reveals interpretable scientific findings like conservation laws and singularities.

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Area of Science:

  • Artificial Intelligence
  • Computational Physics
  • Scientific Discovery

Background:

  • Deep learning offers potential to revolutionize science by providing human-interpretable findings.
  • Current methods often lack transparency, hindering scientific progress.

Purpose of the Study:

  • To develop a novel data-driven approach for a human-machine partnership to accelerate scientific discovery.
  • To create interpretable models of physical systems using deep learning.

Main Methods:

  • Collected physical system responses under Gaussian process excitations.
  • Trained rational neural networks to learn Green's functions of hidden linear partial differential equations.
  • Analyzed learned functions for human-understandable properties.

Main Results:

  • Identified human-understandable properties such as linear conservation laws and symmetries.
  • Located shock and singularity points, boundary effects, and dominant modes.
  • Successfully applied the technique to advection-diffusion, viscous shocks, and Stokes flow.

Conclusions:

  • The developed approach enables a human-machine partnership for accelerated scientific discovery.
  • Rational neural networks can learn interpretable Green's functions from data.
  • This method reveals key physical properties and system behaviors in a human-understandable format.