English

FIRE: Multi-fidelity Regression with Distribution-conditioned In-context Learning using Tabular Foundation Models

Machine Learning 2026-02-02 v1

Abstract

Multi-fidelity (MF) regression often operates in regimes of extreme data imbalance, where the commonly-used Gaussian-process (GP) surrogates struggle with cubic scaling costs and overfit to sparse high-fidelity observations, limiting efficiency and generalization in real-world applications. We introduce FIRE, a training-free MF framework that couples tabular foundation models (TFMs) to perform zero-shot in-context Bayesian inference via a high-fidelity correction model conditioned on the low-fidelity model's posterior predictive distributions. This cross-fidelity information transfer via distributional summaries captures heteroscedastic errors, enabling robust residual learning without model retraining. Across 31 benchmark problems spanning synthetic and real-world tasks (e.g., DrivAerNet, LCBench), FIRE delivers a stronger performance-time trade-off than seven state-of-the-art GP-based or deep learning MF regression methods, ranking highest in accuracy and uncertainty quantification with runtime advantages. Limitations include context window constraints and dependence on the quality of the pre-trained TFM's.

Keywords

Cite

@article{arxiv.2601.22371,
  title  = {FIRE: Multi-fidelity Regression with Distribution-conditioned In-context Learning using Tabular Foundation Models},
  author = {Rosen Ting-Ying Yu and Nicholas Sung and Faez Ahmed},
  journal= {arXiv preprint arXiv:2601.22371},
  year   = {2026}
}
R2 v1 2026-07-01T09:26:48.991Z