Fuzzy semi-Markovian stochastic model for single-unit system with repairman arrival delay under Lindley lifetime distribution using bell-shaped membership function

Monika Saini; Ashish Kumar

doi:10.46481/jnsps.2026.3438

Authors

Monika Saini
Department of Mathematics and Statistics, Manipal University Jaipur, Jaipur-303007, India
Ashish Kumar
[email protected]

Department of Mathematics and Statistics, Manipal University Jaipur, Jaipur-303007, India

Keywords:

Fuzzy Availability, Lindley Distribution, Single-unit system, Bell-shaped membership function, Regenerative point technique

Abstract

The key objective of the present analysis is to analyze the impact of fuzziness and repairman arrival delay on the mean time to system failure (MTSF) and availability of single-unit systems. Using a semi-Markovian approach, two stochastic models were developed, and recursive relations were obtained for the reliability measures. The lifetime, failure time, and repairman arrival time are considered Lindley-distributed random variables, with a parameter represented as a fuzzy number defined by a bell-shaped membership function. The switching devices and repairs are assumed to be as good as new. The numerical results show that increasing the \alpha-cut reduces fuzziness and improves the estimates, while immediate arrival of the repairman increases system availability. The importance of the results is highlighted using a numerical example generated from a Lindley-distributed random sample of size 1000 by considering \varepsilon = 0.1 and dynamic \delta in RStudio.

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Fuzzy semi-Markovian stochastic model for single-unit system with repairman arrival delay under Lindley lifetime distribution using bell-shaped membership function

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