Multi-Valued Decision Diagram-Based Reliability Analysis of &lt;formula formulatype="inline"&gt;&lt;tex Notation="TeX"&gt;$k$&lt;/tex&gt; &lt;/formula&gt;-out-of-&lt;formula formulatype="inline"&gt;&lt;tex Notation="TeX"&gt;$n$&lt;/tex&gt; &lt;/formula&gt; Cold Standby Systems Subject to Scheduled Backups

Zhai, Qingqing; Xing, Liudong; Peng, Rui; Yang, Jun

doi:10.1109/tr.2015.2404891

Cited by 51 publications

(6 citation statements)

References 38 publications

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“…We assume the lifetime of both actuator and mechanical valve follow Weibull distribution, which has been widely adopted to describe the lifetime of mechanical and electronic systems and shows good performance. 36,37 The lifetime CDF of the actuator is 𝐹 1 (𝑡) = 1 − exp[−(𝑡∕12.7) 3.3 ] (unit of time: 10 5 cycles), and the lifetime CDF of the mechanical valve is 𝐹 2 (𝑡) = 1 − exp[−(𝑡∕8.6) 2.1 ] (unit of time: 10 5 cycles). All these parameters can be obtained based on real failure time data with some statistical methods.…”

Section: Numerical Studymentioning

confidence: 99%

“…A solenoid may fail due to coil failure of the actuator, or the mechanical valve failure. We assume the lifetime of both actuator and mechanical valve follow Weibull distribution, which has been widely adopted to describe the lifetime of mechanical and electronic systems and shows good performance 36, 37 . The lifetime CDF of the actuator is

F_1(t)=1-\exp [-(t/12.7)^{3.3}]

(unit of time: 10 5 cycles), and the lifetime CDF of the mechanical valve is

F_2(t)=1-\exp [-(t/8.6)^{2.1}]

(unit of time: 10 5 cycles).…”

Section: Numerical Studymentioning

confidence: 99%

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Maintenance optimization of a two‐component series system considering masked causes of failure

Hu,

Huang,

Shen

2023

Quality & Reliability Eng

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Maintenance planning of two‐component systems has been extensively studied in recent decades. In the literature, most studies assume that the failure cause of a two‐component system is self‐announcing. In some real applications, the failure cause is masked, and a diagnosis with professional equipment is needed to reveal the failed component. This study investigates a preventive replacement policy of a two‐component series system considering masked causes of failure. When an unexpected failure occurs, we can carry out a diagnosis to reveal the failed component and replace it subsequently, or we can directly replace the whole system without diagnosis. Meanwhile, when we carry out a preventive replacement on a component, the other component can be replaced opportunistically. We formulate the problem as a semi‐Markov decision process, and prove the existence of the stationary optimal policy. The optimal preventive replacement age thresholds for each component and the corresponding optimal maintenance actions upon each failure are jointly obtained to minimize the long‐term average maintenance cost per time unit. A comprehensive numerical study is provided to illustrate the effectiveness of our proposed model.

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Section: Numerical Studymentioning

confidence: 99%

F_1(t)=1-\exp [-(t/12.7)^{3.3}]

(unit of time: 10 5 cycles), and the lifetime CDF of the mechanical valve is

F_2(t)=1-\exp [-(t/8.6)^{2.1}]

(unit of time: 10 5 cycles).…”

Section: Numerical Studymentioning

confidence: 99%

Maintenance optimization of a two‐component series system considering masked causes of failure

Hu,

Huang,

Shen

2023

Quality & Reliability Eng

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“…In addition, a mechanical valve can be preventively replaced when its virtual age reaches a threshold. We assume the PDF of the valve lifetime follows a Weibull distribution, which has been widely adopted to describe the lifetime of a mechanical system and shows good performance 47, 48 . The shape parameter and scale parameter are respective

m=2.5

and

\eta =40

, which can be obtained based on real failure time data by maximizing likelihood function 49–51 .…”

Section: Numerical Studymentioning

confidence: 99%

“…We assume the PDF of the valve lifetime follows a Weibull distribution, which has been widely adopted to describe the lifetime of a mechanical system and shows good performance. 47,48 The shape parameter and scale parameter are respective 𝑚 = 2.5 and 𝜂 = 40, which can be obtained based on real failure time data by maximizing likelihood function. [49][50][51] In our study, we use a Beta distribution to model the random quality of the imperfect repair, and the parameters are set as respective 𝛼 = 4 and 𝛽 = 2.…”

Section: A L G O R I T H Mmentioning

confidence: 99%

Preventive replacement policy of a system considering multiple maintenance actions upon a failure

Jiang

2022

Quality & Reliability Eng

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Age‐based preventive replacement policy has been extensively studied in the literature. Upon an unexpected failure, most studies assume that only one type of maintenance actions can be executed to restore the system back to work. For example, minimal repair or corrective replacement that bring the system to respective as‐bad‐as‐old and as‐good‐as‐new states. Few studies consider both two types of maintenance actions, while predetermine the structure of the maintenance policy. Modern systems are becoming increasingly complex. Besides minimal repair and corrective replacement, imperfect repair can also be carried out to restore a failed system back to work, which brings it to a state between as‐bad‐as‐old and as‐good‐as‐new. This study investigates an optimal age‐based replacement policy, where minimal repair, corrective replacement, and imperfect repair can be carried out upon an unexpected failure with different maintenance effects. We formulate the problem as a semi‐Markov decision process (SMDP), and prove the existence of the stationary optimal policy. The optimal preventive replacement age threshold and the corresponding optimal maintenance action upon each failure are jointly obtained to minimize the long‐term average maintenance cost per time unit. A numerical study is provided to illustrate the effectiveness of our proposed model.

show abstract

“…These methods exploit a variety of tools for system reliability modeling and analysis. The widely adopted tools mainly include Monte-Carlo simulation [16,17], universal generating function (UGF) [18][19][20][21][22][23][24][25], multi-valued decision diagram (MDD) [26][27][28][29][30][31][32][33], and minimal cut (MC) vectors/minimal path (MP) vectors to level d (named d-MCs/d-MPs) [34][35][36][37][38][39][40][41][42][43][44][45][46][47][48][49][50][51]. Monte-Carlo simulation is an effective modeling tool, and provides a general method for analyzing multi-state systems.…”

Section: Introductionmentioning

confidence: 99%

A new efficient algorithm for finding all d -minimal cuts in multi-state networks

Niu

Gao

Lam

2017

Reliability Engineering & System Safety

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Multi-Valued Decision Diagram-Based Reliability Analysis of <formula formulatype="inline"><tex Notation="TeX">$k$</tex> </formula>-out-of-<formula formulatype="inline"><tex Notation="TeX">$n$</tex> </formula> Cold Standby Systems Subject to Scheduled Backups

Cited by 51 publications

References 38 publications

Maintenance optimization of a two‐component series system considering masked causes of failure

Maintenance optimization of a two‐component series system considering masked causes of failure

Preventive replacement policy of a system considering multiple maintenance actions upon a failure

A new efficient algorithm for finding all d -minimal cuts in multi-state networks

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