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Main Authors: Denoodt, Fabian, Oramas, José
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2503.15583
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author Denoodt, Fabian
Oramas, José
author_facet Denoodt, Fabian
Oramas, José
contents Since state-of-the-art uncertainty estimation methods are often computationally demanding, we investigate whether incorporating prior information can improve uncertainty estimates in conventional deep neural networks. Our focus is on machine learning tasks where meaningful predictions can be made from sub-parts of the input. For example, in speaker classification, the speech waveform can be divided into sequential patches, each containing information about the same speaker. We observe that the variance between sub-predictions serves as a reliable proxy for uncertainty in such settings. Our proposed variance-based scaling framework produces competitive uncertainty estimates in classification while being less computationally demanding and allowing for integration as a post-hoc calibration tool. This approach also leads to a simple extension of deep ensembles, improving the expressiveness of their predicted distributions.
format Preprint
id arxiv_https___arxiv_org_abs_2503_15583
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Efficient Post-Hoc Uncertainty Calibration via Variance-Based Smoothing
Denoodt, Fabian
Oramas, José
Machine Learning
Since state-of-the-art uncertainty estimation methods are often computationally demanding, we investigate whether incorporating prior information can improve uncertainty estimates in conventional deep neural networks. Our focus is on machine learning tasks where meaningful predictions can be made from sub-parts of the input. For example, in speaker classification, the speech waveform can be divided into sequential patches, each containing information about the same speaker. We observe that the variance between sub-predictions serves as a reliable proxy for uncertainty in such settings. Our proposed variance-based scaling framework produces competitive uncertainty estimates in classification while being less computationally demanding and allowing for integration as a post-hoc calibration tool. This approach also leads to a simple extension of deep ensembles, improving the expressiveness of their predicted distributions.
title Efficient Post-Hoc Uncertainty Calibration via Variance-Based Smoothing
topic Machine Learning
url https://arxiv.org/abs/2503.15583