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Main Authors: Xu, Hua, Arias-Londoño, Julián D., Godino-Llorente, Juan I.
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2602.11973
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author Xu, Hua
Arias-Londoño, Julián D.
Godino-Llorente, Juan I.
author_facet Xu, Hua
Arias-Londoño, Julián D.
Godino-Llorente, Juan I.
contents In critical decision support systems based on medical imaging, the reliability of AI-assisted decision-making is as relevant as predictive accuracy. Although deep learning models have demonstrated significant accuracy, they frequently suffer from miscalibration, manifested as overconfidence in erroneous predictions. To facilitate clinical acceptance, it is imperative that models quantify uncertainty in a manner that correlates with prediction correctness, allowing clinicians to identify unreliable outputs for further review. In order to address this necessity, the present paper proposes a generalizable probabilistic optimization framework grounded in Bayesian deep learning. Specifically, a novel Confidence-Uncertainty Boundary Loss (CUB-Loss) is introduced that imposes penalties on high-certainty errors and low-certainty correct predictions, explicitly enforcing alignment between prediction correctness and uncertainty estimates. Complementing this training-time optimization, a Dual Temperature Scaling (DTS) strategy is devised for post-hoc calibration, further refining the posterior distribution to improve intuitive explainability. The proposed framework is validated on three distinct medical imaging tasks: automatic screening of pneumonia, diabetic retinopathy detection, and identification of skin lesions. Empirical results demonstrate that the proposed approach achieves consistent calibration improvements across diverse modalities, maintains robust performance in data-scarce scenarios, and remains effective on severely imbalanced datasets, underscoring its potential for real clinical deployment.
format Preprint
id arxiv_https___arxiv_org_abs_2602_11973
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Calibrated Bayesian Deep Learning for Explainable Decision Support Systems Based on Medical Imaging
Xu, Hua
Arias-Londoño, Julián D.
Godino-Llorente, Juan I.
Computer Vision and Pattern Recognition
Machine Learning
62F15, 92C55, 68T45
I.4.0; G.3; I.2.1
In critical decision support systems based on medical imaging, the reliability of AI-assisted decision-making is as relevant as predictive accuracy. Although deep learning models have demonstrated significant accuracy, they frequently suffer from miscalibration, manifested as overconfidence in erroneous predictions. To facilitate clinical acceptance, it is imperative that models quantify uncertainty in a manner that correlates with prediction correctness, allowing clinicians to identify unreliable outputs for further review. In order to address this necessity, the present paper proposes a generalizable probabilistic optimization framework grounded in Bayesian deep learning. Specifically, a novel Confidence-Uncertainty Boundary Loss (CUB-Loss) is introduced that imposes penalties on high-certainty errors and low-certainty correct predictions, explicitly enforcing alignment between prediction correctness and uncertainty estimates. Complementing this training-time optimization, a Dual Temperature Scaling (DTS) strategy is devised for post-hoc calibration, further refining the posterior distribution to improve intuitive explainability. The proposed framework is validated on three distinct medical imaging tasks: automatic screening of pneumonia, diabetic retinopathy detection, and identification of skin lesions. Empirical results demonstrate that the proposed approach achieves consistent calibration improvements across diverse modalities, maintains robust performance in data-scarce scenarios, and remains effective on severely imbalanced datasets, underscoring its potential for real clinical deployment.
title Calibrated Bayesian Deep Learning for Explainable Decision Support Systems Based on Medical Imaging
topic Computer Vision and Pattern Recognition
Machine Learning
62F15, 92C55, 68T45
I.4.0; G.3; I.2.1
url https://arxiv.org/abs/2602.11973