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Bibliographic Details
Main Authors: Ai, Jiahao, Ren, Zhimei
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2402.13042
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author Ai, Jiahao
Ren, Zhimei
author_facet Ai, Jiahao
Ren, Zhimei
contents We introduce a fine-grained framework for uncertainty quantification of predictive models under distributional shifts. This framework distinguishes the shift in covariate distributions from that in the conditional relationship between the outcome ($Y$) and the covariates ($X$). We propose to reweight the training samples to adjust for an identifiable covariate shift while protecting against worst-case conditional distribution shift bounded in an $f$-divergence ball. Based on ideas from conformal inference and distributionally robust learning, we present an algorithm that outputs (approximately) valid and efficient prediction intervals in the presence of distributional shifts. As a use case, we apply the framework to sensitivity analysis of individual treatment effects with hidden confounding. The proposed methods are evaluated in simulation studies and four real data applications, demonstrating superior robustness and efficiency compared with existing benchmarks.
format Preprint
id arxiv_https___arxiv_org_abs_2402_13042
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Not all distributional shifts are equal: Fine-grained robust conformal inference
Ai, Jiahao
Ren, Zhimei
Methodology
We introduce a fine-grained framework for uncertainty quantification of predictive models under distributional shifts. This framework distinguishes the shift in covariate distributions from that in the conditional relationship between the outcome ($Y$) and the covariates ($X$). We propose to reweight the training samples to adjust for an identifiable covariate shift while protecting against worst-case conditional distribution shift bounded in an $f$-divergence ball. Based on ideas from conformal inference and distributionally robust learning, we present an algorithm that outputs (approximately) valid and efficient prediction intervals in the presence of distributional shifts. As a use case, we apply the framework to sensitivity analysis of individual treatment effects with hidden confounding. The proposed methods are evaluated in simulation studies and four real data applications, demonstrating superior robustness and efficiency compared with existing benchmarks.
title Not all distributional shifts are equal: Fine-grained robust conformal inference
topic Methodology
url https://arxiv.org/abs/2402.13042