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Main Authors: Ruijs, Sanne, Kosiakova, Alina, Javed, Farrukh
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.10731
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author Ruijs, Sanne
Kosiakova, Alina
Javed, Farrukh
author_facet Ruijs, Sanne
Kosiakova, Alina
Javed, Farrukh
contents Deep neural networks (DNNs) have become integral to a wide range of scientific and practical applications due to their flexibility and strong predictive performance. Despite their accuracy, however, DNNs frequently exhibit poor calibration, often assigning overly confident probabilities to incorrect predictions. This limitation underscores the growing need for integrated mechanisms that provide reliable uncertainty estimation. In this article, we compare two prominent approaches for uncertainty quantification: a Bayesian approximation via Monte Carlo Dropout and the nonparametric Conformal Prediction framework. Both methods are assessed using two convolutional neural network architectures; H-CNN VGG16 and GoogLeNet, trained on the Fashion-MNIST dataset. The empirical results show that although H-CNN VGG16 attains higher predictive accuracy, it tends to exhibit pronounced overconfidence, whereas GoogLeNet yields better-calibrated uncertainty estimates. Conformal Prediction additionally demonstrates consistent validity by producing statistically guaranteed prediction sets, highlighting its practical value in high-stakes decision-making contexts. Overall, the findings emphasize the importance of evaluating model performance beyond accuracy alone and contribute to the development of more reliable and trustworthy deep learning systems.
format Preprint
id arxiv_https___arxiv_org_abs_2603_10731
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Beyond Accuracy: Reliability and Uncertainty Estimation in Convolutional Neural Networks
Ruijs, Sanne
Kosiakova, Alina
Javed, Farrukh
Machine Learning
62P25
I.5.4; I.4.9; G.3
Deep neural networks (DNNs) have become integral to a wide range of scientific and practical applications due to their flexibility and strong predictive performance. Despite their accuracy, however, DNNs frequently exhibit poor calibration, often assigning overly confident probabilities to incorrect predictions. This limitation underscores the growing need for integrated mechanisms that provide reliable uncertainty estimation. In this article, we compare two prominent approaches for uncertainty quantification: a Bayesian approximation via Monte Carlo Dropout and the nonparametric Conformal Prediction framework. Both methods are assessed using two convolutional neural network architectures; H-CNN VGG16 and GoogLeNet, trained on the Fashion-MNIST dataset. The empirical results show that although H-CNN VGG16 attains higher predictive accuracy, it tends to exhibit pronounced overconfidence, whereas GoogLeNet yields better-calibrated uncertainty estimates. Conformal Prediction additionally demonstrates consistent validity by producing statistically guaranteed prediction sets, highlighting its practical value in high-stakes decision-making contexts. Overall, the findings emphasize the importance of evaluating model performance beyond accuracy alone and contribute to the development of more reliable and trustworthy deep learning systems.
title Beyond Accuracy: Reliability and Uncertainty Estimation in Convolutional Neural Networks
topic Machine Learning
62P25
I.5.4; I.4.9; G.3
url https://arxiv.org/abs/2603.10731