Exact equations for the reliability and mean time to failure of 1-out-of-n cold-standby system with imperfect switching
Subject Areas : Business AdministrationSeyed Taghi Akhavan Niaki 1 , Afshin Yaghoubi 2
1 - Sharif University of Technology
2 - Department of Industrial Engineering, Sharif University of Technology, Tehran, Iran
Keywords: Standby redundancy, Cold-standby redundancy, Imperfect switching, Markov method,
Abstract :
Standby redundancy is a common and fundamental technique for increasing the reliability and availability of various systems. Cold-standby state is one of the most important strategies that are well used in non-repairable systems and plays an important role in mission-critical systems reliability, such as space exploration and satellite systems. In this paper, closed-form equations are derived using the Markov method to calculate the reliability function and the meantime to failure of a 1-out-of-n cold-standby system with non-repairable components under imperfect switching. While it is assumed that the failures of the switch and its associated active components are independent of each other, a constant failure rate is considered for the components and an increasing constant failure rate for the switch as it is used more frequently. In the end, numerical examples are solved for a system with various numbers of components to demonstrate the application of the closed-form equations.
Amari, S. V. (2012). Reliability of k-out-of-n standby systems with gamma distributions. Reliability and Maintainability Symposium (RAMS), 2012 Proceedings-Annual. IEEE.
Ardakan, M. A., Hamadani, A. Z. (2014). Reliability–redundancy allocation problem with cold-standby redundancy strategy. Simulation Modelling Practice and Theory, 42, 107-118.
Ardakan, M. A., Rezvan, M. T. (2018). Multi-objective optimization of reliability–redundancy allocation problem with cold-standby strategy using NSGA-II. Reliability Engineering & System Safety 172: 225-238.
Billinton, R., Allan, R. N. (1992). Reliability Evaluation of Engineering Systems. New York: Plenum Press.
Coit, D. W. (2001). Cold-standby redundancy optimization for non-repairable systems. IIE Transactions 33(6): 471-478.
Dhillon, Balbir S. Reliability, quality, and safety for engineers. CRC Press, 2004.
Dwyer, Vincent M., Roger M. Goodall, and Roger Dixon. Reliability of 2-out-of-N: G systems with NHPP failure flows and fixed repair times. International Journal of Reliability, Quality and Safety Engineering 19.01 (2012): 1250003.
Jia, X., Chen, H., Cheng, Z., Guo, B. (2016). A comparison between two switching policies for two-unit standby system. Reliability Engineering & System Safety 148 (C): 109-118.
Kim, Heungseob, and Pansoo Kim. Reliability–redundancy allocation problem considering optimal redundancy strategy using parallel genetic algorithm. Reliability Engineering & System Safety 159 (2017): 153-160.
Lenz, M., Rhodin, J. Reliability calculations for complex systems. Department of Electrical Engineering, Linköpings universitet (2011).
Levitin, G., Xing, L., Dai, Y. Cold-standby sequencing optimization considering mission cost. Reliability Engineering & System Safety 118 (2013): 28-34.
Levitin, G., Xing, L., Dai, Y. Optimal component loading in 1-out-of-N cold standby systems. Reliability Engineering & System Safety 127 (2014): 58-64.
Sharifi, M., Pourkarim Guilani, P., & Shahriari, M. (2016). Using NSGA II Algorithm for a Three Objectives Redundancy Allocation Problem with k-out-of-n Sub-Systems. Journal of Optimization in Industrial Engineering, 9(19), 87-96.
Sharifi, M., & Yaghoubizadeh, M. (2015). Reliability modelling of the redundancy allocation problem in the series-parallel systems and determining the system optimal parameters. Journal of Optimization in Industrial Engineering, 8(17), 67-77.
Wang, C., Xing, L., Amari, S. V. (2012). A fast approximation method for reliability analysis of cold-standby systems. Reliability Engineering & System Safety106 (C): 119-126.
Wang, W., Loman, J. Reliability/availability of K-out-of-N system with M cold standby units. Annual Reliability and Maintainability Symposium. 2002 Proceedings (Cat. No. 02CH37318). IEEE, 2002.
Xing, L., Tannous, O., Dugan, J. B. (2012). Reliability analysis of non-repairable cold-standby systems using sequential binary decision diagrams. IEEE Transactions on Systems, Man, and Cybernetics-Part A: Systems and Humans 42(3): 715-726.
Yaghoubi, A., Niaki, S.T.A., Rostamzadeh, H. A closed-form equation for steady-state availability of cold standby repairable k-out-of-n, International Journal of Quality & Reliability Management 37 (2019): 145-155.
Zhai, Q., Xing, L., Peng, R., Yang, J. Reliability analysis of cold standby system with scheduled backups. 2015 Annual Reliability and Maintainability Symposium (RAMS). IEEE, 2015.