TY - GEN
T1 - Time-dependent Reliability Analysis of a Nonrepairable Multifunctional System Containing Multifunctional Components
AU - Zhao, Jiangbin
AU - Si, Shubin
AU - Cai, Zhiqiang
AU - Liao, Haitao
N1 - Publisher Copyright:
© 2020 IEEE.
PY - 2020/8
Y1 - 2020/8
N2 - A multifunctional system is designed to provide several required functions to accomplish one task or a series of tasks, and the system will fail when at least one function is totally lost. Such a system may contain multifunctional components, for which the lost function of a component can be restored by the same function of another component. To ensure the reliability of the system under a limited budget, the redundancy level of each function must be wisely selected. Moreover, the start-up strategy that determines which components and their functions are to be activated first has a significant impact on system reliability when no maintenance can be performed during operation. In this paper, the lifetimes of components and their functions are assumed to follow exponential distributions. The time-dependent reliability of the system is evaluated by a continuous-time Markov chain model once the start-up strategy and the redundancy levels of components are determined. Two experiments on an onsite monitoring system involving multiple unmanned aerial vehicles are provided to illustrate the effects of failure rates of components and functions, start-up strategy, and redundancy levels on the reliability of the system. To maximize system reliability, the failure rates of components and functions need to be well balanced. Moreover, a start-up strategy involving a less number of activated components results in a higher system reliability over time for the system with given redundancy levels.
AB - A multifunctional system is designed to provide several required functions to accomplish one task or a series of tasks, and the system will fail when at least one function is totally lost. Such a system may contain multifunctional components, for which the lost function of a component can be restored by the same function of another component. To ensure the reliability of the system under a limited budget, the redundancy level of each function must be wisely selected. Moreover, the start-up strategy that determines which components and their functions are to be activated first has a significant impact on system reliability when no maintenance can be performed during operation. In this paper, the lifetimes of components and their functions are assumed to follow exponential distributions. The time-dependent reliability of the system is evaluated by a continuous-time Markov chain model once the start-up strategy and the redundancy levels of components are determined. Two experiments on an onsite monitoring system involving multiple unmanned aerial vehicles are provided to illustrate the effects of failure rates of components and functions, start-up strategy, and redundancy levels on the reliability of the system. To maximize system reliability, the failure rates of components and functions need to be well balanced. Moreover, a start-up strategy involving a less number of activated components results in a higher system reliability over time for the system with given redundancy levels.
KW - continuous-time Markov chain model
KW - multifunctional components
KW - nonrepairable systems
KW - time-dependent reliability
UR - http://www.scopus.com/inward/record.url?scp=85093960932&partnerID=8YFLogxK
U2 - 10.1109/APARM49247.2020.9209390
DO - 10.1109/APARM49247.2020.9209390
M3 - 会议稿件
AN - SCOPUS:85093960932
T3 - 2020 Asia-Pacific International Symposium on Advanced Reliability and Maintenance Modeling, APARM 2020
BT - 2020 Asia-Pacific International Symposium on Advanced Reliability and Maintenance Modeling, APARM 2020
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 2020 Asia-Pacific International Symposium on Advanced Reliability and Maintenance Modeling, APARM 2020
Y2 - 20 August 2020 through 23 August 2020
ER -