English

Sparse Polynomial Chaos expansions using Variational Relevance Vector Machines

Machine Learning 2020-06-24 v1 Machine Learning Computation

Abstract

The challenges for non-intrusive methods for Polynomial Chaos modeling lie in the computational efficiency and accuracy under a limited number of model simulations. These challenges can be addressed by enforcing sparsity in the series representation through retaining only the most important basis terms. In this work, we present a novel sparse Bayesian learning technique for obtaining sparse Polynomial Chaos expansions which is based on a Relevance Vector Machine model and is trained using Variational Inference. The methodology shows great potential in high-dimensional data-driven settings using relatively few data points and achieves user-controlled sparse levels that are comparable to other methods such as compressive sensing. The proposed approach is illustrated on two numerical examples, a synthetic response function that is explored for validation purposes and a low-carbon steel plate with random Young's modulus and random loading, which is modeled by stochastic finite element with 38 input random variables.

Keywords

Cite

@article{arxiv.1912.11029,
  title  = {Sparse Polynomial Chaos expansions using Variational Relevance Vector Machines},
  author = {Panagiotis Tsilifis and Iason Papaioannou and Daniel Straub and Fabio Nobile},
  journal= {arXiv preprint arXiv:1912.11029},
  year   = {2020}
}

Comments

Submitted to Journal of Computational Physics

R2 v1 2026-06-23T12:55:00.676Z