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E-QRGMM: Efficient Generative Metamodeling for Covariate-Dependent Uncertainty Quantification

Machine Learning 2026-01-28 v1 Machine Learning

Abstract

Covariate-dependent uncertainty quantification in simulation-based inference is crucial for high-stakes decision-making but remains challenging due to the limitations of existing methods such as conformal prediction and classical bootstrap, which struggle with covariate-specific conditioning. We propose Efficient Quantile-Regression-Based Generative Metamodeling (E-QRGMM), a novel framework that accelerates the quantile-regression-based generative metamodeling (QRGMM) approach by integrating cubic Hermite interpolation with gradient estimation. Theoretically, we show that E-QRGMM preserves the convergence rate of the original QRGMM while reducing grid complexity from O(n1/2)O(n^{1/2}) to O(n1/5)O(n^{1/5}) for the majority of quantile levels, thereby substantially improving computational efficiency. Empirically, E-QRGMM achieves a superior trade-off between distributional accuracy and training speed compared to both QRGMM and other advanced deep generative models on synthetic and practical datasets. Moreover, by enabling bootstrap-based construction of confidence intervals for arbitrary estimands of interest, E-QRGMM provides a practical solution for covariate-dependent uncertainty quantification.

Keywords

Cite

@article{arxiv.2601.19256,
  title  = {E-QRGMM: Efficient Generative Metamodeling for Covariate-Dependent Uncertainty Quantification},
  author = {Zhiyang Liang and Qingkai Zhang},
  journal= {arXiv preprint arXiv:2601.19256},
  year   = {2026}
}
R2 v1 2026-07-01T09:21:44.417Z