基于双修正分层贝叶斯的零故障 Weibull 情况下的可靠性评估

IF 2.2 3区工程技术 Q3 ENGINEERING, INDUSTRIAL

Quality and Reliability Engineering International Pub Date : 2024-05-08 DOI:10.1002/qre.3572

Bo Zheng, Zuteng Long, Yang Ning, Xin Ma

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引用次数: 0

摘要

在求解零失效可靠性评估模型时，分层贝叶斯或 E-Bayes 经常用于估算失效概率；然而，在实际应用中，使用这些方法进行可靠性估算的精度并不高。有鉴于此，本研究针对 Weibull 特性数据提出了一种新型的双修正分层贝叶斯（DMH-Bayes）方法，以增强失效概率估计能力，提高可靠性点估计精度。同时，为了保证评估结果的一致性和置信度，引入了参数Bootstrap法（P-Bootstrap）和基于点估计的L-矩估计法来获得可靠性置信区间估计值。通过对陀螺仪轴承进行蒙特卡洛模拟测试和分析，证实新模型具有更好的适用性和鲁棒性，同时提高了可靠性评估的准确性。

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Reliability evaluation in the zero‐failure Weibull case based on double‐modified hierarchical Bayes

Hierarchical Bayes, or E‐Bayes, is frequently used to estimate the failure probability when solving a zero‐failure reliability evaluation model; however, the accuracy of the reliability estimation using these methods is not very good in practice. Due to this, a novel double‐modified hierarchical Bayes (DMH‐Bayes) is proposed for Weibull characteristic data in this study to enhance failure probability estimation and improve reliability point estimation accuracy. Meanwhile, in order to guarantee the preservation of the assessment findings' consistency and confidence level, the parametric Bootstrap method (P‐Bootstrap) and the L‐moment estimation method based on point estimation are introduced to obtain reliability confidence interval estimates. Based on Monte–Carlo simulation testing and analysis of a gyroscope bearing, the new model is confirmed to have better applicability and robustness while improving the accuracy of reliability assessment.

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来源期刊

Quality and Reliability Engineering International 管理科学-工程：工业

CiteScore

4.90

自引率

21.70%

发文量

181

审稿时长

6 months

期刊介绍： Quality and Reliability Engineering International is a journal devoted to practical engineering aspects of quality and reliability. A refereed technical journal published eight times per year, it covers the development and practical application of existing theoretical methods, research and industrial practices. Articles in the journal will be concerned with case studies, tutorial-type reviews and also with applications of new or well-known theory to the solution of actual quality and reliability problems in engineering. Papers describing the use of mathematical and statistical tools to solve real life industrial problems are encouraged, provided that the emphasis is placed on practical applications and demonstrated case studies. The scope of the journal is intended to include components, physics of failure, equipment and systems from the fields of electronic, electrical, mechanical and systems engineering. The areas of communications, aerospace, automotive, railways, shipboard equipment, control engineering and consumer products are all covered by the journal. Quality and reliability of hardware as well as software are covered. Papers on software engineering and its impact on product quality and reliability are encouraged. The journal will also cover the management of quality and reliability in the engineering industry. Special issues on a variety of key topics are published every year and contribute to the enhancement of Quality and Reliability Engineering International as a major reference in its field.