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Autori principali: Holstege, Floris, Wouters, Bram, van Giersbergen, Noud, Diks, Cees
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2410.14315
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author Holstege, Floris
Wouters, Bram
van Giersbergen, Noud
Diks, Cees
author_facet Holstege, Floris
Wouters, Bram
van Giersbergen, Noud
Diks, Cees
contents A distribution shift between the training and test data can severely harm performance of machine learning models. Importance weighting addresses this issue by assigning different weights to data points during training. We argue that existing heuristics for determining the weights are suboptimal, as they neglect the increase of the variance of the estimated model due to the finite sample size of the training data. We interpret the optimal weights in terms of a bias-variance trade-off, and propose a bi-level optimization procedure in which the weights and model parameters are optimized simultaneously. We apply this optimization to existing importance weighting techniques for last-layer retraining of deep neural networks in the presence of sub-population shifts and show empirically that optimizing weights significantly improves generalization performance.
format Preprint
id arxiv_https___arxiv_org_abs_2410_14315
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Optimizing importance weighting in the presence of sub-population shifts
Holstege, Floris
Wouters, Bram
van Giersbergen, Noud
Diks, Cees
Machine Learning
A distribution shift between the training and test data can severely harm performance of machine learning models. Importance weighting addresses this issue by assigning different weights to data points during training. We argue that existing heuristics for determining the weights are suboptimal, as they neglect the increase of the variance of the estimated model due to the finite sample size of the training data. We interpret the optimal weights in terms of a bias-variance trade-off, and propose a bi-level optimization procedure in which the weights and model parameters are optimized simultaneously. We apply this optimization to existing importance weighting techniques for last-layer retraining of deep neural networks in the presence of sub-population shifts and show empirically that optimizing weights significantly improves generalization performance.
title Optimizing importance weighting in the presence of sub-population shifts
topic Machine Learning
url https://arxiv.org/abs/2410.14315