Physics-informed machine learning for system reliability analysis and design with partially observed information

IF 9.4 1区 工程技术 Q1 ENGINEERING, INDUSTRIAL Reliability Engineering & System Safety Pub Date : 2024-10-30 DOI:10.1016/j.ress.2024.110598
Yanwen Xu , Parth Bansal , Pingfeng Wang , Yumeng Li
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Abstract

Constructing a high-fidelity predictive model is crucial for analyzing complex systems, optimizing system design, and enhancing system reliability. Although Gaussian Process (GP) models are well-known for their capability to quantify uncertainty, they rely heavily on data and necessitate a large representative dataset to establish a high-fidelity predictive model. Physics-informed Machine Learning (PIML) has emerged as a way to integrate prior physics knowledge and machine learning models. However, current PIML methods are generally based on fully observed datasets and mainly suffer from two challenges: (1) effectively utilize partially available information from multiple sources of varying dimensions and fidelity; (2) incorporate physics knowledge while maintaining the mathematical properties of the GP-based model and uncertainty quantification capability of the predictive model. To overcome these limitations, this paper proposes a novel physics-informed machine learning method that incorporates physics prior knowledge and multi-source data by leveraging latent variables through the Bayesian framework. This method effectively utilizes partially available limited information, significantly reduces the need for costly fully observed data, and improves prediction accuracy while maintaining the model property of uncertainty quantification. The developed approach has been demonstrated with two case studies: the vehicle design problem and the battery capacity loss prediction. The case study results demonstrate the effectiveness of the proposed model in complex system design and optimization while propagating uncertainty with limited fully observed data.
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利用部分观测信息进行系统可靠性分析和设计的物理信息机器学习
构建高保真预测模型对于分析复杂系统、优化系统设计和提高系统可靠性至关重要。尽管高斯过程(GP)模型以其量化不确定性的能力而闻名,但它们在很大程度上依赖于数据,因此需要一个具有代表性的大型数据集来建立高保真预测模型。物理信息机器学习(PIML)作为一种整合先验物理知识和机器学习模型的方法应运而生。然而,目前的 PIML 方法一般基于完全观测数据集,主要面临两个挑战:(1) 有效利用来自不同维度和保真度的多个来源的部分可用信息;(2) 结合物理知识,同时保持基于 GP 的模型的数学特性和预测模型的不确定性量化能力。为了克服这些局限性,本文提出了一种新颖的物理信息机器学习方法,该方法通过贝叶斯框架利用潜在变量,将物理先验知识和多源数据结合起来。该方法有效地利用了部分可用的有限信息,大大减少了对成本高昂的完全观测数据的需求,并在保持不确定性量化模型特性的同时提高了预测精度。所开发的方法通过两个案例研究得到了验证:车辆设计问题和电池容量损失预测。案例研究结果证明了所提出的模型在复杂系统设计和优化中的有效性,同时利用有限的完全观测数据传播不确定性。
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来源期刊
Reliability Engineering & System Safety
Reliability Engineering & System Safety 管理科学-工程:工业
CiteScore
15.20
自引率
39.50%
发文量
621
审稿时长
67 days
期刊介绍: Elsevier publishes Reliability Engineering & System Safety in association with the European Safety and Reliability Association and the Safety Engineering and Risk Analysis Division. The international journal is devoted to developing and applying methods to enhance the safety and reliability of complex technological systems, like nuclear power plants, chemical plants, hazardous waste facilities, space systems, offshore and maritime systems, transportation systems, constructed infrastructure, and manufacturing plants. The journal normally publishes only articles that involve the analysis of substantive problems related to the reliability of complex systems or present techniques and/or theoretical results that have a discernable relationship to the solution of such problems. An important aim is to balance academic material and practical applications.
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