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Auteurs principaux: Ueno, Maomi, Zhang, Enbo, Fuchimoto, Kazuma, Chiba, Satoshi, Chen, Jingde, Ishizuka, Chikako
Format: Preprint
Publié: 2026
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Accès en ligne:https://arxiv.org/abs/2603.29100
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author Ueno, Maomi
Zhang, Enbo
Fuchimoto, Kazuma
Chiba, Satoshi
Chen, Jingde
Ishizuka, Chikako
author_facet Ueno, Maomi
Zhang, Enbo
Fuchimoto, Kazuma
Chiba, Satoshi
Chen, Jingde
Ishizuka, Chikako
contents The fission product yield (FPY) is crucially important information for numerous nuclear applications. However, the peak-shaped characteristics of FPY data present important challenges for predicting unobservable FPY data. To address these challenges, after applying Multi-task learning models to fission product yield data and their experimental error estimates, we introduce a novel loss function along with incorporation of the odd even effect. Our approach is intended to predict unknown fission yields and the associated experimental error. To demonstrate the effectiveness of our proposed method, we compared our proposed method with conventional methods that learn each dataset independently. Our findings demonstrate that the proposed methods can predict peak shaped data with experimental error estimates more effectively than earlier methods can.
format Preprint
id arxiv_https___arxiv_org_abs_2603_29100
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Multi-task deep neural network for predicting both nuclear fission yields and their experimental errors in peak-shaped data
Ueno, Maomi
Zhang, Enbo
Fuchimoto, Kazuma
Chiba, Satoshi
Chen, Jingde
Ishizuka, Chikako
Nuclear Theory
The fission product yield (FPY) is crucially important information for numerous nuclear applications. However, the peak-shaped characteristics of FPY data present important challenges for predicting unobservable FPY data. To address these challenges, after applying Multi-task learning models to fission product yield data and their experimental error estimates, we introduce a novel loss function along with incorporation of the odd even effect. Our approach is intended to predict unknown fission yields and the associated experimental error. To demonstrate the effectiveness of our proposed method, we compared our proposed method with conventional methods that learn each dataset independently. Our findings demonstrate that the proposed methods can predict peak shaped data with experimental error estimates more effectively than earlier methods can.
title Multi-task deep neural network for predicting both nuclear fission yields and their experimental errors in peak-shaped data
topic Nuclear Theory
url https://arxiv.org/abs/2603.29100