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Paper detail

Sparse Polynomial Chaos expansions using Variational Relevance Vector Machines

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.

preprint2019arXivOpen access
Panagiotis TsilifisIason PapaioannouDaniel StraubFabio Nobile
ComputationMachine Learning
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Panagiotis TsilifisIason PapaioannouDaniel StraubFabio Nobile

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