Expert‐in‐the‐loop design of integral nuclear data experiments

IF 2.1 4区数学 Q3 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

Statistical Analysis and Data Mining Pub Date : 2024-04-02 DOI:10.1002/sam.11677

Isaac Michaud, Michael Grosskopf, Jesson Hutchinson, Scott Vander Wiel

引用次数: 0

Abstract

Nuclear data are fundamental inputs to radiation transport codes used for reactor design and criticality safety. The design of experiments to reduce nuclear data uncertainty has been a challenge for many years, but advances in the sensitivity calculations of radiation transport codes within the last two decades have made optimal experimental design possible. The design of integral nuclear experiments poses numerous challenges not emphasized in classical optimal design, in particular, constrained design spaces (in both a statistical and engineering sense), severely under‐determined systems, and optimality uncertainty. We present a design pipeline to optimize critical experiments that uses constrained Bayesian optimization within an iterative expert‐in‐the‐loop framework. We show a successfully completed experiment campaign designed with this framework that involved two critical configurations and multiple measurements that targeted compensating errors in 239Pu nuclear data.

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核数据整体实验的在环专家设计

核数据是用于反应堆设计和临界安全的辐射输运代码的基本输入。多年来，降低核数据不确定性的实验设计一直是一项挑战，但在过去二十年中，辐射传输代码灵敏度计算的进步使得优化实验设计成为可能。整体核实验设计提出了许多经典优化设计中没有强调的挑战，特别是受限设计空间（统计和工程学意义上的）、严重欠定系统和优化不确定性。我们介绍了一种优化关键实验的设计管道，它在迭代专家在环框架内使用受限贝叶斯优化。我们展示了利用该框架设计的一次成功完成的实验活动，该活动涉及两个关键配置和针对 239Pu 核数据误差补偿的多次测量。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Statistical Analysis and Data Mining COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCEC-COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS

CiteScore

3.20

自引率

7.70%

发文量

期刊介绍： Statistical Analysis and Data Mining addresses the broad area of data analysis, including statistical approaches, machine learning, data mining, and applications. Topics include statistical and computational approaches for analyzing massive and complex datasets, novel statistical and/or machine learning methods and theory, and state-of-the-art applications with high impact. Of special interest are articles that describe innovative analytical techniques, and discuss their application to real problems, in such a way that they are accessible and beneficial to domain experts across science, engineering, and commerce. The focus of the journal is on papers which satisfy one or more of the following criteria: Solve data analysis problems associated with massive, complex datasets Develop innovative statistical approaches, machine learning algorithms, or methods integrating ideas across disciplines, e.g., statistics, computer science, electrical engineering, operation research. Formulate and solve high-impact real-world problems which challenge existing paradigms via new statistical and/or computational models Provide survey to prominent research topics.