Data driven Z-FFR physical modeling

Conference on Computer Graphics, Artificial Intelligence, and Data Processing Pub Date : 2023-05-23 DOI:10.1117/12.2674673

W. Xiong, Zhangchun Tang, Pan Liu, Qiang Gao, Yan Shi, Fanyu Qu, Chencheng Liu, Cheng Liu

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引用次数: 3

Abstract

The Z-FFR (Z-Pinch Driven Fusion Fission Hybrid Reactor) is an important innovative design concept. The high uncertainty of the operating process of the pulsed power unit and the physical process of fusion and the absence of some theoretical and experimental conditions make it difficult to establish a high-precision mechanistic model, and it is difficult to obtain an accurate mathematical model of a complex, dynamic system. A data-driven physical modelling approach is urgently needed to replace the mechanistic models obtained with the aid of extensive simulations and experiments. The approach includes the creation of functional modules, the packaging of sub-modules, the configuration of module interfaces and the configuration of analytical models. Based on the actual needs of Z-FFR design and operation monitoring, the online analysis can be autonomously configured to accommodate different experimental data through machine learning, enabling anomaly detection, trend prediction, model design evaluation and operation assessment during the experimental process.

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数据驱动的Z-FFR物理建模

Z-FFR (Z-Pinch - Driven Fusion - Fission Hybrid Reactor)是一个重要的创新设计理念。脉冲功率单元工作过程和核聚变物理过程的高度不确定性以及某些理论和实验条件的缺乏，使得高精度的机理模型难以建立，复杂的动态系统难以获得精确的数学模型。迫切需要一种数据驱动的物理建模方法来取代借助大量模拟和实验获得的机理模型。该方法包括功能模块的创建、子模块的打包、模块接口的配置和分析模型的配置。根据Z-FFR设计和运行监测的实际需要，通过机器学习，可以自主配置在线分析，以适应不同的实验数据，实现实验过程中的异常检测、趋势预测、模型设计评估和运行评估。

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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Conference on Computer Graphics, Artificial Intelligence, and Data Processing

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