Uncertainty quantification of a physics-informed model based on sparse identification of a Thermal Energy Distribution System

IF 2.3 3区工程技术 Q1 NUCLEAR SCIENCE & TECHNOLOGY

Annals of Nuclear Energy Pub Date : 2025-09-17 DOI:10.1016/j.anucene.2025.111865

Paul Seurin, Linyu Lin

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引用次数: 0

Abstract

Integrated energy systems (IES)s are crucial for enhancing the economy and efficiency of power generation sources (e.g., nuclear energy) necessary to unleash American energy dominance. These systems can be integrated with thermal energy storage (TES) and intermittent renewable energies to optimize overall energy use, peak-load regulation, and demand-side responses. However, the stabilization of energy generation, transport, and utilization introduces operational complexities that exceed the challenges of managing each sub-component individually. Currently, though IESs rely on human operators for efficiency and stability, reducing human error risk and enhancing performance through automation is highly desirable. Recent advances at Idaho National Laboratory have demonstrated successful control of the Thermal Energy Distributed System (TEDS). However, the automatic control system depends on a deterministic Sparse Identification of Nonlinear Dynamics with Control (SINDyC) model, which are trained based on simulation data from physics-based simulations. Because of uncertainties in physics-based simulation, SINDyC model results in large discrepancies against experimental data and cannot be reliably used in automatic control. In this paper, we present an innovative approach to address these discrepancies by quantifying uncertainties and developing a more robust model. We first generated trajectories by using first-principles physics codes to encapsulate the experiment. Next, we trained thousands of models by randomly sampling these trajectories. We then collapsed all those models into one probabilistic SINDyC by fitting a multivariate Gaussian distribution onto the resulting coefficient’s distribution. Despite its simplicity, our approach successfully produced 95% confidence intervals that captured the experimental trajectories. It even did so with a higher probability and better U-pooling score across six of the seven relevant quantities of interest (QoIs), as compared to other classical approaches. Ongoing research is focusing on generating new experimental trajectories to validate this approach, and on employing Bayesian calibration to refine parametric uncertainties and guide future model development efforts.

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基于热能分配系统稀疏识别的物理信息模型的不确定性量化

综合能源系统（IES）对于提高发电资源（如核能）的经济性和效率至关重要，这是释放美国能源主导地位所必需的。这些系统可以与热能储存（TES）和间歇性可再生能源集成，以优化整体能源使用、峰值负荷调节和需求侧响应。然而，能源生产、运输和利用的稳定性带来的操作复杂性超过了单独管理每个子组件的挑战。目前，虽然工业自动化在效率和稳定性方面较少依赖人工操作员，但通过自动化减少人为错误风险并提高性能是非常可取的。爱达荷国家实验室最近的进展已经证明了对热能分布式系统（TEDS）的成功控制。然而，自动控制系统依赖于非线性动力学控制的确定性稀疏识别（SINDyC）模型，该模型是基于物理模拟的仿真数据训练的。由于基于物理的仿真存在不确定性，SINDyC模型与实验数据存在较大差异，不能可靠地用于自动控制。在本文中，我们提出了一种创新的方法，通过量化不确定性和开发一个更稳健的模型来解决这些差异。我们首先通过使用第一性原理物理代码来封装实验来生成轨迹。接下来，我们通过随机采样这些轨迹来训练数千个模型。然后，我们通过将多元高斯分布拟合到结果系数的分布上，将所有这些模型分解为一个概率SINDyC。尽管它很简单，我们的方法成功地产生了95%的置信区间，捕获了实验轨迹。与其他经典方法相比，它甚至在7个相关兴趣量（qoi）中的6个上具有更高的概率和更好的u池得分。正在进行的研究重点是生成新的实验轨迹来验证该方法，并使用贝叶斯校准来细化参数不确定性并指导未来的模型开发工作。

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

Annals of Nuclear Energy 工程技术-核科学技术

CiteScore

4.30

自引率

21.10%

发文量

632

审稿时长

7.3 months

期刊介绍： Annals of Nuclear Energy provides an international medium for the communication of original research, ideas and developments in all areas of the field of nuclear energy science and technology. Its scope embraces nuclear fuel reserves, fuel cycles and cost, materials, processing, system and component technology (fission only), design and optimization, direct conversion of nuclear energy sources, environmental control, reactor physics, heat transfer and fluid dynamics, structural analysis, fuel management, future developments, nuclear fuel and safety, nuclear aerosol, neutron physics, computer technology (both software and hardware), risk assessment, radioactive waste disposal and reactor thermal hydraulics. Papers submitted to Annals need to demonstrate a clear link to nuclear power generation/nuclear engineering. Papers which deal with pure nuclear physics, pure health physics, imaging, or attenuation and shielding properties of concretes and various geological materials are not within the scope of the journal. Also, papers that deal with policy or economics are not within the scope of the journal.