Performance Analysis of Multi-State k-out-of-n System using Sumudu Transform with Fermatean Fuzzy Sets

doi:10.23940/ijpe.25.12.p5.714724

Abstract

Abstract: This research investigates the reliability and availability of a multi-state k-out-of-n system composed of three interconnected subsystems: main power supply units, backup generators, and uninterruptible power supply units. Each subsystem operates under specific failure and repair protocols, including warm and cold standby arrangements. State transitions are modeled using stochastic processes, and the Sumudu transform technique is employed to solve the complex differential equations governing the system's behavior. Fermatean fuzzy sets are incorporated to effectively manage uncertainty. Numerical illustrations evaluate availability and reliability under various scenarios, demonstrating the influence of failure rates, maintenance delays, and repair personnel availability on system performance. The fuzzy approach provides a broader range of reliability and availability estimates compared to traditional Markov methods. The integration of advanced mathematical tools and Fermatean fuzzy logic enhances decision-making, maintenance planning, and cost optimization, enabling the design of robust, efficient, and cost-effective systems in complex engineering environments with prevalent uncertainties.

Key words: reliability, availability, multi-state k-out-of-n system, sumudu transform, fermatean fuzzy set

G. Hemalatha and G. Vijayalakshmi. Performance Analysis of Multi-State k-out-of-n System using Sumudu Transform with Fermatean Fuzzy Sets [J]. Int J Performability Eng, 2025, 21(12): 714-724.

Add to citation manager EndNote|Reference Manager|ProCite|BibTeX|RefWorks

References

[1] Watugala G.K.,1993. Sumudu transform: a new integral transform to solve differential equations and control engineering problems. Integrated Education,24(1), pp. 35-43.
[2] Senapati T., and Yager R.R., 2020. Fermatean fuzzy sets. Journal of Ambient Intelligence and Humanized Computing,11(2), pp. 663-674.
[3] Joe H.,1997. Multivariate Models and Multivariate Dependence Concepts. CRC press.
[4] Nelsen R.B.,2006. An Introduction to Copulas. New York, NY: Springer New York.
[5] Kumar A., and Singh S.B., 2008. Reliability analysis of an n-unit parallel standby system under imperfect switching using copula. Computer Modeling and New Technologies,12(1), pp. 47-55.
[6] Ram M., and Singh S.B., 2008. Availability and cost analysis of a parallel redundant complex system with two types of failure under preemptive-resume repair discipline using Gumbel-Hougaard family copula in repair. International Journal of Reliability, Quality and Safety Engineering,15(04), pp. 341-365.
[7] Ram M., and Singh S.B., 2010. Availability, MTTF and cost analysis of complex system under preemptive‐repeat repair discipline using gumbel‐hougaard family copula. International Journal of Quality & Reliability Management,27(5), pp. 576-595.
[8] Singh V.V., Poonia P.K., and Adbullahi A.H., 2020. Performance analysis of a complex repairable system with two subsystems in series configuration with an imperfect switch. J. Math. Comput. Sci.,10(2), pp. 359-383.
[9] Singh V.V., Poonia P.K., Labaran J.U., and Abdullahi I., 2021. Probabilistic analysis of a multi-state warm standby k-out-of-n: G system in a series configuration using copula linguists. Reliability: Theory & Applications,16(2 (62)), pp. 22-39.
[10] Chakravarthy S.R., Krishnamoorthy A., and Ushakumari P.V., 2001. A k‐out‐of‐n reliability system with an unreliable server and phase type repairs and services: the (N, T) policy. International Journal of Stochastic Analysis,14(4), pp. 361-380.
[11] Chachra A., Kumar A., and Ram M., 2024. A markovian approach to reliability estimation of series-parallel system with fermatean fuzzy sets.Computers & Industrial Engineering, 190, 110081.
[12] Wang W., and Feng Y., 2022. A fermatean fuzzy multi-criteria group decision making approach based on reliability for the evaluation of Indian electronics manufacturing firms.Procedia Computer Science, 214, pp. 26-33.
[13] Zadeh L.A.,1965. Fuzzy sets. Information and Control,8(3), pp. 338-353.
[14] Atanassov K.T.,1999. Intuitionistic fuzzy sets. InIntuitionistic Fuzzy Sets: Theory and Applications, pp. 1-137.
[15] Ashraf S., Attaullah, Naeem M., Khan A., Rehman N., and Pandit M.K., 2023. Novel information measures for fermatean fuzzy sets and their applications to pattern recognition and medical diagnosis.Computational Intelligence and Neuroscience, 2023(1), 9273239.