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A bandit-learning approach to multifidelity approximation

Numerical Analysis 2022-02-22 v3 Numerical Analysis Applications Machine Learning

Abstract

Multifidelity approximation is an important technique in scientific computation and simulation. In this paper, we introduce a bandit-learning approach for leveraging data of varying fidelities to achieve precise estimates of the parameters of interest. Under a linear model assumption, we formulate a multifidelity approximation as a modified stochastic bandit, and analyze the loss for a class of policies that uniformly explore each model before exploiting. Utilizing the estimated conditional mean-squared error, we propose a consistent algorithm, adaptive Explore-Then-Commit (AETC), and establish a corresponding trajectory-wise optimality result. These results are then extended to the case of vector-valued responses, where we demonstrate that the algorithm is efficient without the need to worry about estimating high-dimensional parameters. The main advantage of our approach is that we require neither hierarchical model structure nor \textit{a priori} knowledge of statistical information (e.g., correlations) about or between models. Instead, the AETC algorithm requires only knowledge of which model is a trusted high-fidelity model, along with (relative) computational cost estimates of querying each model. Numerical experiments are provided at the end to support our theoretical findings.

Keywords

Cite

@article{arxiv.2103.15342,
  title  = {A bandit-learning approach to multifidelity approximation},
  author = {Yiming Xu and Vahid Keshavarzzadeh and Robert M. Kirby and Akil Narayan},
  journal= {arXiv preprint arXiv:2103.15342},
  year   = {2022}
}

Comments

41 pages, 10 figures, corrected some typos

R2 v1 2026-06-24T00:38:07.923Z