Morad Alizadeh;Mahmoud Afshari;Javier E. Contreras-Reyes;Danial Mazarei;Haitham M. Yousof
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引用次数: 0
Abstract
Threshold risk analysis based on extreme stress data assess the probability of events that exceeds a certain threshold in a dataset characterized by extreme values or stresses. This type of analysis is often used in finance, insurance, environmental science, and engineering, where understanding and managing extreme events are crucial. This article proposed the extended Gompertz (ExGo) model for analyzing Mean of Order P (MOOP$_{[ P] }$) and statistical threshold risk analysis based on real extreme stress data. This study examined the statistical properties of the proposed model and its efficiency. Several estimation methods (maximum likelihood, Anderson–Darling, ordinary least squares, Cramér–von Mises, weighted least squares, and right-tail Anderson–Darling), were evaluated through simulations and experiments to determine their effectiveness. The comparisons were based on bias and the root mean square error. Additionally, proposed distribution was applied to reliability and stress data, demonstrating its applicability and flexibility in modeling. This study focused on MOOP$_{ [ P] }$ analysis using the ExGo model to determine the optimal parameter P, crucial for extreme stress data analysis in engineering and reliability contexts. Furthermore, proposed distribution is employed in various risk measurement and analysis indicators, including value-at-risk, tail-value-at-risk, tail variance, and tail mean-variance indicators, with emphasis on their application in reliability and engineering, particularly concerning change in stress data and breaking stress data.
基于极端应力数据的阈值风险分析评估了以极端值或应力为特征的数据集中超过一定阈值的事件的概率。这种类型的分析通常用于金融、保险、环境科学和工程领域,在这些领域,理解和管理极端事件至关重要。本文基于真实极端应力数据,提出了用于分析P阶均值(MOOP$_{[P]}$)和统计阈值风险分析的扩展Gompertz (ExGo)模型。本研究检验了所提出模型的统计特性及其效率。通过模拟和实验对几种估计方法(极大似然、Anderson-Darling、普通最小二乘、cram - von Mises、加权最小二乘和右尾Anderson-Darling)进行了评估,以确定其有效性。比较基于偏倚和均方根误差。此外,将该分布应用于可靠性和应力数据,证明了其建模的适用性和灵活性。研究重点是使用ExGo模型进行MOOP$_{[P]}$分析,以确定最优参数P,这对于工程和可靠性环境中的极端应力数据分析至关重要。并将所提出的分布应用于风险值、风险尾值、尾部方差和尾部均值方差等各种风险度量和分析指标,重点介绍了它们在可靠性和工程中的应用,特别是在应力数据变化和断裂应力数据中的应用。
期刊介绍:
IEEE Transactions on Reliability is a refereed journal for the reliability and allied disciplines including, but not limited to, maintainability, physics of failure, life testing, prognostics, design and manufacture for reliability, reliability for systems of systems, network availability, mission success, warranty, safety, and various measures of effectiveness. Topics eligible for publication range from hardware to software, from materials to systems, from consumer and industrial devices to manufacturing plants, from individual items to networks, from techniques for making things better to ways of predicting and measuring behavior in the field. As an engineering subject that supports new and existing technologies, we constantly expand into new areas of the assurance sciences.
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