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Bibliographic Details
Main Authors: Feldman, Shai, Romano, Yaniv
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2406.05405
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author Feldman, Shai
Romano, Yaniv
author_facet Feldman, Shai
Romano, Yaniv
contents We develop a method to generate prediction sets with a guaranteed coverage rate that is robust to corruptions in the training data, such as missing or noisy variables. Our approach builds on conformal prediction, a powerful framework to construct prediction sets that are valid under the i.i.d assumption. Importantly, naively applying conformal prediction does not provide reliable predictions in this setting, due to the distribution shift induced by the corruptions. To account for the distribution shift, we assume access to privileged information (PI). The PI is formulated as additional features that explain the distribution shift, however, they are only available during training and absent at test time. We approach this problem by introducing a novel generalization of weighted conformal prediction and support our method with theoretical coverage guarantees. Empirical experiments on both real and synthetic datasets indicate that our approach achieves a valid coverage rate and constructs more informative predictions compared to existing methods, which are not supported by theoretical guarantees.
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id arxiv_https___arxiv_org_abs_2406_05405
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Robust Conformal Prediction Using Privileged Information
Feldman, Shai
Romano, Yaniv
Machine Learning
We develop a method to generate prediction sets with a guaranteed coverage rate that is robust to corruptions in the training data, such as missing or noisy variables. Our approach builds on conformal prediction, a powerful framework to construct prediction sets that are valid under the i.i.d assumption. Importantly, naively applying conformal prediction does not provide reliable predictions in this setting, due to the distribution shift induced by the corruptions. To account for the distribution shift, we assume access to privileged information (PI). The PI is formulated as additional features that explain the distribution shift, however, they are only available during training and absent at test time. We approach this problem by introducing a novel generalization of weighted conformal prediction and support our method with theoretical coverage guarantees. Empirical experiments on both real and synthetic datasets indicate that our approach achieves a valid coverage rate and constructs more informative predictions compared to existing methods, which are not supported by theoretical guarantees.
title Robust Conformal Prediction Using Privileged Information
topic Machine Learning
url https://arxiv.org/abs/2406.05405