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Kernel-based active subspaces with application to computational fluid dynamics parametric problems using the

Francesco Romor1, Marco Tezzele1, Andrea Lario1

  • 1Mathematics Area, mathLab, SISSA Scuola Internazionale Superiore di Studi Avanzati Trieste Italy.

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Summary
This summary is machine-generated.

This study introduces a novel kernel-based nonlinear method for dimension reduction, enhancing parameter space exploration and response surface design for complex simulations.

Keywords:
active subspacesdimension reductiondiscontinuous Galerkinkernel methodsridge approximation

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Area of Science:

  • Computational mathematics
  • Applied mathematics
  • Scientific computing

Background:

  • Active subspaces method offers effective dimension reduction for parameter spaces.
  • Nonlinear extensions have shown promise in improving response surface design.
  • Existing methods face challenges with complex, high-dimensional problems.

Purpose of the Study:

  • To develop and present a novel kernel-based nonlinear method for dimension reduction.
  • To extend the mathematical framework for parameter space reduction of multivariate functions.
  • To demonstrate the method's efficacy on challenging benchmarks and in a practical application.

Main Methods:

  • Kernel-based nonlinear dimension reduction.
  • Extension of active subspaces methodology.
  • Application to parametric computational fluid dynamics (CFD) using the discontinuous Galerkin method.

Main Results:

  • The proposed method achieves effective dimension reduction in parameter spaces.
  • Successful implementation and testing on challenging benchmarks, outperforming existing methods.
  • Demonstration of a complete pipeline for response surface design in CFD.

Conclusions:

  • The kernel-based nonlinear method provides a powerful tool for dimension reduction and response surface design.
  • The methodology offers significant advantages for complex parametric modeling, particularly in CFD.
  • This work advances the field of dimension reduction for scientific and engineering applications.