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Area of Science:

  • Physics
  • Applied Mathematics
  • Data Science

Background:

  • Dimensional analysis is crucial for understanding physical systems, especially when governing equations are unknown.
  • The Buckingham Pi theorem offers a method for finding dimensionless groups but doesn't guarantee uniqueness or optimal data collapse.
  • Existing methods often require prior knowledge of system dynamics or governing equations.

Purpose of the Study:

  • To develop automated, data-driven techniques for discovering optimal dimensionless groups.
  • To leverage measurement data's inherent symmetries for identifying these groups.
  • To reduce the dimensionality of complex physical system data effectively.

Main Methods:

  • Proposed three novel data-driven techniques constrained by the Buckingham Pi theorem.
  • Method 1: Constrained optimization with non-parametric fitting.
  • Method 2: A deep learning approach (BuckiNet) for parameter space projection.
  • Method 3: Sparse identification of nonlinear dynamics for discovering dimensionless equations.

Main Results:

  • Successfully identified key dimensionless groups in three benchmark problems: a bead on a rotating hoop, laminar boundary layer, and Rayleigh-Bénard convection.
  • Demonstrated the accuracy, robustness, and computational efficiency of the developed methods.
  • Showcased the ability of these techniques to collapse data effectively into a lower-dimensional space.

Conclusions:

  • The proposed data-driven methods offer a powerful, automated approach to dimensional analysis.
  • These techniques enhance the discovery of physical symmetries and insights from measurement data.
  • The methods provide a robust alternative for analyzing systems lacking explicit governing equations.