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Fast Surrogate Modeling using Dimensionality Reduction in Model Inputs and Field Output: Application to Additive

Manav Vohra1, Paromita Nath1, Sankaran Mahadevan1

  • 1Department of Civil and Environmental Engineering, Vanderbilt University, Nashville, TN 37235.

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Summary
This summary is machine-generated.

This study introduces a new surrogate modeling method that reduces dimensions in both input and output data. This approach significantly speeds up computational analysis for complex engineering problems like additive manufacturing.

Keywords:
Surrogate modelactive subspaceadditive manufacturingdimension reductionprincipal componentsresidual stress

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Area of Science:

  • Computational Engineering
  • Materials Science
  • Data Science

Background:

  • Surrogate modeling is crucial for efficient analysis of complex systems.
  • Parameter dimension reduction techniques offer potential for computational speed-ups.
  • Additive manufacturing processes involve significant stochastic variability.

Purpose of the Study:

  • To develop a novel surrogate modeling approach combining principal component analysis (PCA) and active subspace (AS) methodology.
  • To achieve computational efficiency by reducing dimensions in both input and output spaces.
  • To apply the developed method to analyze variability in residual stress in additively manufactured components.

Main Methods:

  • Identification of principal components (PCs) and features in output field data.
  • Application of active subspace (AS) methodology to map input variables to output features.
  • Development of the Principal Component Active Subspace (PCAS) method for dual dimension reduction.
  • Demonstration on a realistic additive manufacturing problem with stochastic inputs.

Main Results:

  • The PCAS method effectively reduces dimensionality in both input and output domains.
  • The surrogate model enabled efficient uncertainty propagation and identification of stress hotspots.
  • Global sensitivity analysis quantified the impact of uncertain inputs on stress variability.

Conclusions:

  • The PCAS method offers substantial computational gains for surrogate modeling, particularly in generating training data.
  • This approach has enormous potential for advancing control and optimization in additive manufacturing.
  • The developed surrogate model provides valuable insights into stress variability and its sources.