A novel iterative approach of lifetime estimation for standby systems with deteriorating spare parts

•A general iterative method of SSL estimation for stochastic degradation processes is first proposed.•Analytical expressions of SSL’s PDF based on Wiener-process-based model are obtained.•The unit-to-unit variability is described by a Gaussian Mixture Model.•Some analytical results of SSL’s mean and...

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Published inReliability engineering & system safety Vol. 201; p. 106960
Main Authors Zhang, Jian-Xun, Si, Xiao-Sheng, Du, Dang-Bo, Hu, Chang-Hua, Hu, Chen
Format Journal Article
LanguageEnglish
Published Barking Elsevier Ltd 01.09.2020
Elsevier BV
Subjects
Component reliability
Degradation
Deterioration
Fault tolerance
Hypotheses
Iterative algorithms
Iterative methods
Mathematical analysis
Redundancy
Reliability engineering
Spare parts
Standby redundancy
Standby system’s lifetime
Stochastic process
Storage degradation
System effectiveness
Transition probabilities
Wiener process
Standby redundancy
PDF
CDF
PHM
Storage degradation
RUL
Wiener process
Standby system’s lifetime
BM
FPT
Stochastic process
SSL
Online AccessGet full text
ISSN0951-8320
1879-0836
DOI10.1016/j.ress.2020.106960

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Abstract •A general iterative method of SSL estimation for stochastic degradation processes is first proposed.•Analytical expressions of SSL’s PDF based on Wiener-process-based model are obtained.•The unit-to-unit variability is described by a Gaussian Mixture Model.•Some analytical results of SSL’s mean and variance are provided under a nonstorage-failure assumption. Standby redundancy is an effective fault-tolerant technique for enhancing reliability and prolonging the standby system’s operating lifetime. How to estimate the total lifetime of a standby system with a predetermined number of standby components (i.e., spare parts) presents an interesting practical issue. Most existing studies, however, have mainly focused on the lifetime or remaining useful lifetime prediction of a single online product. Moreover, spare parts usually deteriorate in storage, which will worsen their performance and even lead to failure. This makes lifetime estimation for a standby system more challenging. This study, therefore, focused on how to estimate a standby system’s lifetime (SSL) with deteriorating spare parts. Unlike prior work, we fully considered the uncertainty and randomness caused by the spare parts’ storage degradation in the SSL estimation. By establishing the transition probability function of the storage degradation process, we first proposed a general iterative algorithm for SSL estimation under the concept of the first passage time (FPT) and provided the proof based on mathematical induction. Then, we extended this result to a Wiener-process-based model and obtained the iterative result in a single integral form. Moreover, we attained the analytical expressions of SSL mean and variance under a non-storage-failure hypothesis and further provided the requirement for the establishment of the hypothesis. Finally, a numerical case and a practical case of the gyroscope are introduced for illustration.
AbstractList Standby redundancy is an effective fault-tolerant technique for enhancing reliability and prolonging the standby system's operating lifetime. How to estimate the total lifetime of a standby system with a predetermined number of standby components (i.e., spare parts) presents an interesting practical issue. Most existing studies, however, have mainly focused on the lifetime or remaining useful lifetime prediction of a single online product. Moreover, spare parts usually deteriorate in storage, which will worsen their performance and even lead to failure. This makes lifetime estimation for a standby system more challenging. This study, therefore, focused on how to estimate a standby system's lifetime (SSL) with deteriorating spare parts. Unlike prior work, we fully considered the uncertainty and randomness caused by the spare parts' storage degradation in the SSL estimation. By establishing the transition probability function of the storage degradation process, we first proposed a general iterative algorithm for SSL estimation under the concept of the first passage time (FPT) and provided the proof based on mathematical induction. Then, we extended this result to a Wiener-process-based model and obtained the iterative result in a single integral form. Moreover, we attained the analytical expressions of SSL mean and variance under a non-storage-failure hypothesis and further provided the requirement for the establishment of the hypothesis. Finally, a numerical case and a practical case of the gyroscope are introduced for illustration.
•A general iterative method of SSL estimation for stochastic degradation processes is first proposed.•Analytical expressions of SSL’s PDF based on Wiener-process-based model are obtained.•The unit-to-unit variability is described by a Gaussian Mixture Model.•Some analytical results of SSL’s mean and variance are provided under a nonstorage-failure assumption. Standby redundancy is an effective fault-tolerant technique for enhancing reliability and prolonging the standby system’s operating lifetime. How to estimate the total lifetime of a standby system with a predetermined number of standby components (i.e., spare parts) presents an interesting practical issue. Most existing studies, however, have mainly focused on the lifetime or remaining useful lifetime prediction of a single online product. Moreover, spare parts usually deteriorate in storage, which will worsen their performance and even lead to failure. This makes lifetime estimation for a standby system more challenging. This study, therefore, focused on how to estimate a standby system’s lifetime (SSL) with deteriorating spare parts. Unlike prior work, we fully considered the uncertainty and randomness caused by the spare parts’ storage degradation in the SSL estimation. By establishing the transition probability function of the storage degradation process, we first proposed a general iterative algorithm for SSL estimation under the concept of the first passage time (FPT) and provided the proof based on mathematical induction. Then, we extended this result to a Wiener-process-based model and obtained the iterative result in a single integral form. Moreover, we attained the analytical expressions of SSL mean and variance under a non-storage-failure hypothesis and further provided the requirement for the establishment of the hypothesis. Finally, a numerical case and a practical case of the gyroscope are introduced for illustration.
ArticleNumber 106960
Author Zhang, Jian-Xun
Si, Xiao-Sheng
Hu, Chen
Du, Dang-Bo
Hu, Chang-Hua
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SSID ssj0004957
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Snippet •A general iterative method of SSL estimation for stochastic degradation processes is first proposed.•Analytical expressions of SSL’s PDF based on...
Standby redundancy is an effective fault-tolerant technique for enhancing reliability and prolonging the standby system's operating lifetime. How to estimate...
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StartPage 106960
SubjectTerms Component reliability
Degradation
Deterioration
Fault tolerance
Hypotheses
Iterative algorithms
Iterative methods
Mathematical analysis
Redundancy
Reliability engineering
Spare parts
Standby redundancy
Standby system’s lifetime
Stochastic process
Storage degradation
System effectiveness
Transition probabilities
Wiener process
Title A novel iterative approach of lifetime estimation for standby systems with deteriorating spare parts
URI https://dx.doi.org/10.1016/j.ress.2020.106960
https://www.proquest.com/docview/2505414017
Volume 201
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