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Autori principali: Capitaine, Aymeric, Haddouche, Maxime, Moulines, Eric, Jordan, Michael I., Boursier, Etienne, Durmus, Alain
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2505.13564
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author Capitaine, Aymeric
Haddouche, Maxime
Moulines, Eric
Jordan, Michael I.
Boursier, Etienne
Durmus, Alain
author_facet Capitaine, Aymeric
Haddouche, Maxime
Moulines, Eric
Jordan, Michael I.
Boursier, Etienne
Durmus, Alain
contents Decision-focused learning (DFL) is an increasingly popular paradigm for training predictive models whose outputs are used in decision-making tasks. Instead of merely optimizing for predictive accuracy, DFL trains models to directly minimize the loss associated with downstream decisions. However, existing studies focus solely on scenarios where a fixed batch of data is available and the objective function does not change over time. We instead investigate DFL in dynamic environments where the objective function and data distribution evolve over time. This setting is challenging for online learning because the objective function has zero or undefined gradients, which prevents the use of standard first-order optimization methods, and is generally non-convex. To address these difficulties, we (i) regularize the objective to make it differentiable and (ii) use perturbation techniques along with a near-optimal oracle to overcome non-convexity. Combining those techniques yields two original online algorithms tailored for DFL, for which we establish respectively static and dynamic regret bounds. These are the first provable guarantees for the online decision-focused problem. Finally, we showcase the effectiveness of our algorithms on a knapsack experiment, where they outperform two standard benchmarks.
format Preprint
id arxiv_https___arxiv_org_abs_2505_13564
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Online Decision-Focused Learning
Capitaine, Aymeric
Haddouche, Maxime
Moulines, Eric
Jordan, Michael I.
Boursier, Etienne
Durmus, Alain
Machine Learning
Decision-focused learning (DFL) is an increasingly popular paradigm for training predictive models whose outputs are used in decision-making tasks. Instead of merely optimizing for predictive accuracy, DFL trains models to directly minimize the loss associated with downstream decisions. However, existing studies focus solely on scenarios where a fixed batch of data is available and the objective function does not change over time. We instead investigate DFL in dynamic environments where the objective function and data distribution evolve over time. This setting is challenging for online learning because the objective function has zero or undefined gradients, which prevents the use of standard first-order optimization methods, and is generally non-convex. To address these difficulties, we (i) regularize the objective to make it differentiable and (ii) use perturbation techniques along with a near-optimal oracle to overcome non-convexity. Combining those techniques yields two original online algorithms tailored for DFL, for which we establish respectively static and dynamic regret bounds. These are the first provable guarantees for the online decision-focused problem. Finally, we showcase the effectiveness of our algorithms on a knapsack experiment, where they outperform two standard benchmarks.
title Online Decision-Focused Learning
topic Machine Learning
url https://arxiv.org/abs/2505.13564