{"title":"A pythagorean fuzzy approach to consecutive k-out-of-r-from-n system reliability modelling","authors":"Aayushi Chachra, Mangey Ram, Akshay Kumar","doi":"10.1007/s13198-024-02435-3","DOIUrl":null,"url":null,"abstract":"<p>The linear consecutive (LC) <i>k</i>-out-of-<i>r</i>-from-<i>n</i> system is an incredibly important configuration used in various engineering systems. Such a system will break down if at least <i>k</i> out of <i>r</i> consecutive elements become inoperable in a system consisting of <i>n</i> ordered components. For any system, the critical necessity is that it should be reliable and remain in a properly functioning state for a stipulated period of time, thus, making it necessary to evaluate the reliability of such systems as well. However, the conventional reliability evaluation methods fail to consider the fuzziness or prospect of errors while computing the reliability, which can be resolved by incorporating fuzzy theory. This particular work presents a novel method for the computation of fuzzy reliability and its sensitivity for an LC <i>k</i>-out-of-<i>r</i>-from-<i>n</i> system, where its inherent fuzziness is addressed with the help of Pythagorean fuzzy sets (PFS), by representing the fuzzy variables as a trapezoidal Pythagorean fuzzy number (TrPFN), due to its ability to consider both membership and non-membership values, unlike the traditional fuzzy sets. Moreover, the universal generating function (UGF) technique is used to obtain the reliability function. Further, two different distributions are considered to represent the failure rates, namely, the Weibull and Pareto distributions and it was established that the Pareto distribution yields better results than the Weibull distribution. The obtained results are then compared with the help of both tabular and graphical illustrations.</p>","PeriodicalId":14463,"journal":{"name":"International Journal of System Assurance Engineering and Management","volume":null,"pages":null},"PeriodicalIF":1.6000,"publicationDate":"2024-08-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"International Journal of System Assurance Engineering and Management","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1007/s13198-024-02435-3","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q2","JCRName":"ENGINEERING, MULTIDISCIPLINARY","Score":null,"Total":0}
引用次数: 0
Abstract
The linear consecutive (LC) k-out-of-r-from-n system is an incredibly important configuration used in various engineering systems. Such a system will break down if at least k out of r consecutive elements become inoperable in a system consisting of n ordered components. For any system, the critical necessity is that it should be reliable and remain in a properly functioning state for a stipulated period of time, thus, making it necessary to evaluate the reliability of such systems as well. However, the conventional reliability evaluation methods fail to consider the fuzziness or prospect of errors while computing the reliability, which can be resolved by incorporating fuzzy theory. This particular work presents a novel method for the computation of fuzzy reliability and its sensitivity for an LC k-out-of-r-from-n system, where its inherent fuzziness is addressed with the help of Pythagorean fuzzy sets (PFS), by representing the fuzzy variables as a trapezoidal Pythagorean fuzzy number (TrPFN), due to its ability to consider both membership and non-membership values, unlike the traditional fuzzy sets. Moreover, the universal generating function (UGF) technique is used to obtain the reliability function. Further, two different distributions are considered to represent the failure rates, namely, the Weibull and Pareto distributions and it was established that the Pareto distribution yields better results than the Weibull distribution. The obtained results are then compared with the help of both tabular and graphical illustrations.
线性连续(LC)k-out-of-r-from-n 系统是各种工程系统中使用的一种极其重要的配置。在一个由 n 个有序元件组成的系统中,如果 r 个连续元件中至少有 k 个无法工作,这样的系统就会崩溃。对于任何系统来说,最重要的是必须可靠,并在规定的时间内保持正常运行状态,因此也有必要对此类系统的可靠性进行评估。然而,传统的可靠性评估方法在计算可靠性时没有考虑到模糊性或可能出现的错误,而模糊理论可以解决这一问题。与传统的模糊集不同,毕达哥拉斯模糊集(PFS)能同时考虑成员值和非成员值,因此能将模糊变量表示为梯形毕达哥拉斯模糊数(TrPFN),从而解决了系统固有的模糊性问题。此外,还使用了通用生成函数(UGF)技术来获得可靠性函数。此外,还考虑了两种不同的分布来表示故障率,即 Weibull 分布和 Pareto 分布。然后,在表格和图形的帮助下对获得的结果进行了比较。
期刊介绍:
This Journal is established with a view to cater to increased awareness for high quality research in the seamless integration of heterogeneous technologies to formulate bankable solutions to the emergent complex engineering problems.
Assurance engineering could be thought of as relating to the provision of higher confidence in the reliable and secure implementation of a system’s critical characteristic features through the espousal of a holistic approach by using a wide variety of cross disciplinary tools and techniques. Successful realization of sustainable and dependable products, systems and services involves an extensive adoption of Reliability, Quality, Safety and Risk related procedures for achieving high assurancelevels of performance; also pivotal are the management issues related to risk and uncertainty that govern the practical constraints encountered in their deployment. It is our intention to provide a platform for the modeling and analysis of large engineering systems, among the other aforementioned allied goals of systems assurance engineering, leading to the enforcement of performance enhancement measures. Achieving a fine balance between theory and practice is the primary focus. The Journal only publishes high quality papers that have passed the rigorous peer review procedure of an archival scientific Journal. The aim is an increasing number of submissions, wide circulation and a high impact factor.