English

Multi-fidelity surrogate modeling using long short-term memory networks

Numerical Analysis 2022-12-21 v2 Machine Learning Numerical Analysis

Abstract

When evaluating quantities of interest that depend on the solutions to differential equations, we inevitably face the trade-off between accuracy and efficiency. Especially for parametrized, time dependent problems in engineering computations, it is often the case that acceptable computational budgets limit the availability of high-fidelity, accurate simulation data. Multi-fidelity surrogate modeling has emerged as an effective strategy to overcome this difficulty. Its key idea is to leverage many low-fidelity simulation data, less accurate but much faster to compute, to improve the approximations with limited high-fidelity data. In this work, we introduce a novel data-driven framework of multi-fidelity surrogate modeling for parametrized, time-dependent problems using long short-term memory (LSTM) networks, to enhance output predictions both for unseen parameter values and forward in time simultaneously - a task known to be particularly challenging for data-driven models. We demonstrate the wide applicability of the proposed approaches in a variety of engineering problems with high- and low-fidelity data generated through fine versus coarse meshes, small versus large time steps, or finite element full-order versus deep learning reduced-order models. Numerical results show that the proposed multi-fidelity LSTM networks not only improve single-fidelity regression significantly, but also outperform the multi-fidelity models based on feed-forward neural networks.

Keywords

Cite

@article{arxiv.2208.03115,
  title  = {Multi-fidelity surrogate modeling using long short-term memory networks},
  author = {Paolo Conti and Mengwu Guo and Andrea Manzoni and Jan S. Hesthaven},
  journal= {arXiv preprint arXiv:2208.03115},
  year   = {2022}
}
R2 v1 2026-06-25T01:30:27.096Z