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Main Authors: Müller, Jens, Kühmichel, Lars, Rohbeck, Martin, Radev, Stefan T., Köthe, Ullrich
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2312.10107
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author Müller, Jens
Kühmichel, Lars
Rohbeck, Martin
Radev, Stefan T.
Köthe, Ullrich
author_facet Müller, Jens
Kühmichel, Lars
Rohbeck, Martin
Radev, Stefan T.
Köthe, Ullrich
contents In this work, we analyze the conditions under which information about the context of an input $X$ can improve the predictions of deep learning models in new domains. Following work in marginal transfer learning in Domain Generalization (DG), we formalize the notion of context as a permutation-invariant representation of a set of data points that originate from the same domain as the input itself. We offer a theoretical analysis of the conditions under which this approach can, in principle, yield benefits, and formulate two necessary criteria that can be easily verified in practice. Additionally, we contribute insights into the kind of distribution shifts for which the marginal transfer learning approach promises robustness. Empirical analysis shows that our criteria are effective in discerning both favorable and unfavorable scenarios. Finally, we demonstrate that we can reliably detect scenarios where a model is tasked with unwarranted extrapolation in out-of-distribution (OOD) domains, identifying potential failure cases. Consequently, we showcase a method to select between the most predictive and the most robust model, circumventing the well-known trade-off between predictive performance and robustness.
format Preprint
id arxiv_https___arxiv_org_abs_2312_10107
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Towards Context-Aware Domain Generalization: Understanding the Benefits and Limits of Marginal Transfer Learning
Müller, Jens
Kühmichel, Lars
Rohbeck, Martin
Radev, Stefan T.
Köthe, Ullrich
Machine Learning
Artificial Intelligence
In this work, we analyze the conditions under which information about the context of an input $X$ can improve the predictions of deep learning models in new domains. Following work in marginal transfer learning in Domain Generalization (DG), we formalize the notion of context as a permutation-invariant representation of a set of data points that originate from the same domain as the input itself. We offer a theoretical analysis of the conditions under which this approach can, in principle, yield benefits, and formulate two necessary criteria that can be easily verified in practice. Additionally, we contribute insights into the kind of distribution shifts for which the marginal transfer learning approach promises robustness. Empirical analysis shows that our criteria are effective in discerning both favorable and unfavorable scenarios. Finally, we demonstrate that we can reliably detect scenarios where a model is tasked with unwarranted extrapolation in out-of-distribution (OOD) domains, identifying potential failure cases. Consequently, we showcase a method to select between the most predictive and the most robust model, circumventing the well-known trade-off between predictive performance and robustness.
title Towards Context-Aware Domain Generalization: Understanding the Benefits and Limits of Marginal Transfer Learning
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2312.10107