Component importance in coherent systems with exchangeable components

This paper is concerned with the Birnbaum importance measure of a component in a binary coherent system. A representation for the Birnbaum importance of a component is obtained when the system consists of exchangeable dependent components. The results are closely related to the concept of the signature of a coherent system. Some examples are presented to illustrate the results.

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COMBINATORIAL APPROACH TO COMPUTING COMPONENT IMPORTANCE INDEXES IN COHERENT SYSTEMS

Probability in the Engineering and Informational Sciences ◽

10.1017/s026996481100026x ◽

2011 ◽

Vol 26 (1) ◽

pp. 117-128 ◽

Cited By ~ 17

Author(s):

Ilya B. Gertsbakh ◽

Yoseph Shpungin

Keyword(s):

System Reliability ◽

Simple Formula ◽

Analytic Formula ◽

Importance Measure ◽

Coherent Systems ◽

Joint Reliability ◽

Component Importance ◽

Definition Of ◽

Combinatorial Parameter ◽

Combinatorial Representation

We consider binary coherent systems with independent binary components having equal failure probability q. The system DOWN probability is expressed via its signature's combinatorial analogue, the so-called D-spectrum. Using the definition of the Birnbaum importance measure (BIM), we introduce for each component a new combinatorial parameter, so-called BIM-spectrum, and develop a simple formula expressing component BIM via the component BIM-spectrum. Further extension of this approach allows obtaining a combinatorial representation for the joint reliability importance (JRI) of two components. To estimate component BIMs and JRIs, there is no need to know the analytic formula for system reliability. We demonstrate how our method works using the Monte Carlo approach. We present several examples of estimating component importance measures in a network when the DOWN state is defined as the loss of terminal connectivity.

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Representations of component importance for coherent systems with exchangeable components

Journal of Applied Probability ◽

10.1017/jpr.2020.2 ◽

2020 ◽

Vol 57 (2) ◽

pp. 385-406

Author(s):

S. Pitzen ◽

M. Burkschat

Keyword(s):

Order Statistics ◽

Distribution Functions ◽

Importance Measure ◽

Coherent Systems ◽

Sequential Order ◽

Limiting Behavior ◽

Sequential Order Statistics ◽

Component Importance ◽

Dependent Component ◽

Two Measures

AbstractTwo definitions of Birnbaum’s importance measure for coherent systems are studied in the case of exchangeable components. Representations of these measures in terms of distribution functions of the ordered component lifetimes are given. As an example, coherent systems with failure-dependent component lifetimes based on the notion of sequential order statistics are considered. Furthermore, it is shown that the two measures are ordered in the case of associated component lifetimes. Finally, the limiting behavior of the measures with respect to time is examined.

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Active Redundancy Allocation in Coherent Systems

Probability in the Engineering and Informational Sciences ◽

10.1017/s0269964800000899 ◽

1988 ◽

Vol 2 (3) ◽

pp. 343-353 ◽

Cited By ~ 62

Author(s):

Philip J. Boland ◽

Emad El Neweihi ◽

Frank Proschan

Keyword(s):

Parallel Systems ◽

Coherent System ◽

Coherent Systems ◽

Redundancy Allocation ◽

Structural Importance ◽

Component Importance ◽

Series Systems ◽

Made In ◽

Parallel Series

We introduce in this paper a new measure of component importance, called redundancy importance, in coherent systems. It is a measure of importance for the situation in which an active redundancy is to be made in a coherent system. This measure of component importance is compared with both the (Birnbaum) reliability importance and the structural importance of a component in a coherent system. Various models of component redundancy are studied, with particular reference to k/out / of / n systems, parallel-series systems, and series-parallel systems.

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Risk Importance Measures for Maintenance in Non-Coherent Systems

18th International Conference on Nuclear Engineering: Volume 2 ◽

10.1115/icone18-29321 ◽

2010 ◽

Cited By ~ 1

Author(s):

Ye Tao ◽

Lixuan Lu

Keyword(s):

Nuclear Power ◽

Power Plants ◽

Weak Links ◽

Coherent System ◽

Level Control ◽

Coherent Systems ◽

Component Importance ◽

Wide Range ◽

Undesired Event ◽

Importance Analysis

Probabilistic Safety Assessment (PSA) has been an important tool to assist Nuclear Power Plants (NPPs) management over the years. Through PSA, the weak links of the whole system can be identified by component importance measures. The importance measures can be classified according to risk significance and safety significance. They signify the role that each component plays in either causing or contributing to the occurrence of an undesired event. A wide range of importance measures have been developed over the years and most of them are geared towards coherent systems. Importance analysis of non-coherent system is rather limited. In this paper, a set of component importance measures for non-coherent systems is analyzed and investigated. The comparison and the selection of the most informative and appropriate measures for guiding the maintenance of a system are presented. A steam generator level control system of NPP is used to demonstrate the application of the results.

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Performance Improvement of a Multi-State Coherent System using Component Importance Measure

American Journal of Mathematical and Management Sciences ◽

10.1080/01966324.2018.1551733 ◽

2019 ◽

Vol 38 (3) ◽

pp. 312-324 ◽

Cited By ~ 1

Author(s):

Soma Roychowdhury ◽

Debasis Bhattacharya

Keyword(s):

Performance Improvement ◽

Importance Measure ◽

Coherent System ◽

Component Importance

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The number of failed components in a coherent working system when the lifetimes are discretely distributed

Metrika ◽

10.1007/s00184-021-00817-2 ◽

2021 ◽

Author(s):

Krzysztof Jasiński

Keyword(s):

Random Variables ◽

Continuous Case ◽

Coherent System ◽

Coherent Systems ◽

Discrete Random Variables ◽

Independent And Identically Distributed

AbstractIn this paper, we study the number of failed components of a coherent system. We consider the case when the component lifetimes are discrete random variables that may be dependent and non-identically distributed. Firstly, we compute the probability that there are exactly i, $$i=0,\ldots ,n-k,$$ i = 0 , … , n - k , failures in a k-out-of-n system under the condition that it is operating at time t. Next, we extend this result to other coherent systems. In addition, we show that, in the most popular model of independent and identically distributed component lifetimes, the obtained probability corresponds to the respective one derived in the continuous case and existing in the literature.

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On the equivalence of systems of different sizes, with applications to system comparisons

Advances in Applied Probability ◽

10.1017/apr.2016.3 ◽

2016 ◽

Vol 48 (2) ◽

pp. 332-348 ◽

Cited By ~ 10

Author(s):

Bo H. Lindqvist ◽

Francisco J. Samaniego ◽

Arne B. Huseby

Keyword(s):

Optimization Problem ◽

Coherent System ◽

Sufficient Condition ◽

Equivalent System ◽

Coherent Systems ◽

Two Systems ◽

Equivalent Systems ◽

Engineered Systems ◽

Signature Vector ◽

Mixed Systems

Abstract The signature of a coherent system is a useful tool in the study and comparison of lifetimes of engineered systems. In order to compare two systems of different sizes with respect to their signatures, the smaller system needs to be represented by an equivalent system of the same size as the larger system. In the paper we show how to construct equivalent systems by adding irrelevant components to the smaller system. This leads to simpler proofs of some current key results, and throws new light on the interpretation of mixed systems. We also present a sufficient condition for equivalence of systems of different sizes when restricting to coherent systems. In cases where for a given system there is no equivalent system of smaller size, we characterize the class of lower-sized systems with a signature vector which stochastically dominates the signature of the larger system. This setup is applied to an optimization problem in reliability economics.

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On relative ageing of coherent systems with dependent identically distributed components

Advances in Applied Probability ◽

10.1017/apr.2019.63 ◽

2020 ◽

Vol 52 (1) ◽

pp. 348-376

Author(s):

Nil Kamal Hazra ◽

Neeraj Misra

Keyword(s):

Sufficient Conditions ◽

System Level ◽

Hazard Rates ◽

Coherent System ◽

Coherent Systems ◽

Component Level ◽

Distributed Components ◽

Two Systems

AbstractRelative ageing describes how one system ages with respect to another. The ageing faster orders are used to compare the relative ageing of two systems. Here, we study ageing faster orders in the hazard and reversed hazard rates. We provide some sufficient conditions for one coherent system to dominate another with respect to ageing faster orders. Further, we investigate whether the active redundancy at the component level is more effective than that at the system level with respect to ageing faster orders, for a coherent system. Furthermore, a used coherent system and a coherent system made out of used components are compared with respect to ageing faster orders.

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ON RELATIVE AGING COMPARISONS OF COHERENT SYSTEMS WITH IDENTICALLY DISTRIBUTED COMPONENTS

Probability in the Engineering and Informational Sciences ◽

10.1017/s0269964820000066 ◽

2020 ◽

pp. 1-15 ◽

Cited By ~ 1

Author(s):

Nil Kamal Hazra ◽

Neeraj Misra

Keyword(s):

Hazard Rate ◽

Sufficient Conditions ◽

Stochastic Orders ◽

Coherent System ◽

Coherent Systems ◽

Cumulative Hazard ◽

Numerical Examples ◽

Distributed Components ◽

Rate Functions ◽

Important Notion

The relative aging is an important notion which is useful to measure how a system ages relative to another one. Among the existing stochastic orders, there are two important orders describing the relative aging of two systems, namely, aging faster orders in the cumulative hazard and the cumulative reversed hazard rate functions. In this paper, we give some sufficient conditions under which one coherent system ages faster than another one with respect to the aforementioned stochastic orders. Further, we show that the proposed sufficient conditions are satisfied for k-out-of-n systems. Moreover, some numerical examples are given to illustrate the applications of proposed results.

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