Reliability analysis of a two-unit standby system under Marshall–Olkin dependency
International Journal of Quality & Reliability Management
ISSN: 0265-671X
Article publication date: 12 December 2022
Issue publication date: 23 May 2023
Abstract
Purpose
One of the common approaches to improve systems reliability is using standby redundancy. Although many works are available in the literature on the applications of standby redundancy, the system components are assumed to be independent of each other. But, in reality, the system components can be dependent on one another, causing the failure of each component to affect the failure rate of the remaining active components. In this paper, a standby two-unit system is considered, assuming a dependency between the switch and its associated active component.
Design/methodology/approach
This paper assumes that the failures between the switch and its associated active component follow the Marshall–Olkin exponential bivariate exponential distribution. Then, the reliability analysis of the system is done using the continuous-time Markov chain method.
Findings
The derived equations application to determine the system steady-state availability, system reliability and sensitivity analysis on the mean time to failure is demonstrated using a numerical illustration.
Originality/value
All previous models assumed independency between the switch and the associated active unit in the standby redundancy approach. In this paper, the switch and its associated component are assumed to be dependent on each other.
Keywords
Acknowledgements
The authors are thankful for the construction comments provided by the reviewers. Taking care of the comments improved the presentation of this paper significantly.
Citation
Yaghoubi, A. and Niaki, S.T.A. (2023), "Reliability analysis of a two-unit standby system under Marshall–Olkin dependency", International Journal of Quality & Reliability Management, Vol. 40 No. 6, pp. 1587-1596. https://doi.org/10.1108/IJQRM-11-2020-0366
Publisher
:Emerald Publishing Limited
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