On the Marshall–Olkin Copula Model for Network Reliability Under Dependent Failures

Matus, Omar; Barrera, Javiera; Moreno, Eduardo; Rubino, Gerardo

doi:10.1109/tr.2018.2865707

Cited by 20 publications

(15 citation statements)

References 29 publications

(34 reference statements)

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“…Also, another interesting venue of work is to tackle models with dependency among the links' states (which, as works such as [23] explain, can have an important impact in reliability values). In particular, it seems possible to apply the proposed method to cases where the dependence can be represented by a set of exponential random variables, like the case of the Marshall-Olkin copula distributions (arising from shock -and anti-shock-models with exponential time arrivals), which have been studied in the case of traditional network reliability in [24], [25] and [26], and can be extended to multi-level link capacity distributions. , 2009), and co-authored several of its chapters.…”

Section: Discussionmentioning

confidence: 99%

Efficient Estimation of Stochastic Flow Network Reliability

2019

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The Creation Process is an algorithm that transforms a static network model into a dynamic one. It is the basis of different variance reduction methods designed to make efficient reliability estimations on highly reliable networks in which links can only assume two possible values, operational or failed. In this article the Creation Process is extended to let it operate on network models in which links can assume more than two values. The proposed algorithm, called here Multi-Level Creation Process, is the basis of a method, also introduced here, to make efficient reliability estimations of highly reliable stochastic flow networks. The method proposed, which consists in an application of Splitting over the Multi-Level Creation Process, is empirically shown to be accurate, efficient, and robust.

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Section: Discussionmentioning

confidence: 99%

Efficient Estimation of Stochastic Flow Network Reliability

2019

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“…In some real-world situations, the nature of the problem can lead to natural simplifications that reduce the number of parameters, e.g., in portfolio-credit risks or in insurance; see [3]. In this line, [24] propose a Lasso selection model to obtain the parameters. Another way to address the explosive number of parameters is to impose exchangeability of the components' lifetimes, as is the case of the LFMO model proposed by [17] and that we will discuss in detail in Section 2.…”

Section: Literature Reviewmentioning

confidence: 99%

Limit distributions of the upper order statistics for the Lévy-frailty Marshall-Olkin distribution

Barrera,

Lagos

2018

Preprint

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The Marshall-Olkin (MO) distribution has been considered a key model in reliability theory and in risk analysis, where it is used to model the lifetimes of dependent components or entities of a system and dependency is induced by "shocks" that hit one or more components at a time. Of particular interest is the Lévy-frailty subfamily of the Marshall-Olkin (LFMO) distribution, since it has few parameters and because the nontrivial dependency structure is driven by an underlying Lévy subordinator process. The main contribution of our work is that we derive the precise asymptotic behavior of the upper order statistics of the LFMO distribution. More specifically, we consider a sequence of n univariate random variables jointly distributed as a multivariate LFMO distribution and analyze the order statistics of the sequence as n grows. Our main result states that if the underlying Lévy subordinator is in the normal domain of attraction of a stable distribution with index of stability α then, after certain logarithmic centering and scaling, the upper order statistics converge in distribution to a stable distribution if α > 1 or a simple transformation of it if α ≤ 1. Our result is especially useful in network reliability and systemic risk, when modeling the lifetimes of components in a system using the LFMO distribution, as it allows to understand the behavior of systems that rely on its last working components. Our result can also give easily computable confidence intervals for these components, provided that a proper convergence analysis is carried out first.

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“…The strong correlations these faults show made them unsuited for analysis under the independent failures assumption. If independence is assumed, it tends to overestimate the reliability [13] and could lead to less reliable designs [14]. As communication networks are undoubtedly an essential part of the critical infrastructure, their proper functioning in post-disaster periods is crucial.…”

Section: Introductionmentioning

confidence: 99%

Communication Network Reliability under geographically correlated failures using Probabilistic Seismic Hazard Analysis

Barrera¹,

Jiménez-Álvarez²,

Cancela³

2023

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<p>The reliability of networks exposed to large disasters has grasped the research community's attention and has become a critical concern in network studies during the last decade. Looking at the damages caused by recent disasters, with earthquakes top the list of those showing more significant impacts on communication networks, and simultaneously, the least predictable events. This study uses the Probabilistic Seismic Hazard Analysis method to estimate the network element state after an earthquake. The approach considers a seismic source model and ground prediction equations to assess the intensity measure for each element according to its location. In the simulation, nodes fail according to the building's fragility curves. Similarly, links fail according to a failure rate estimated based on the intensity measure and the cable's characteristics. We use the source-terminal, and the diameter constrained reliability metrics. The approach goes beyond the graph representation of the network accounting for the seismic risk in the geographical region where the network is embedded. Incorporating the terrain characteristics and the component's robustness into the network performance analysis at an a ordable computational cost.</p>

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On the Marshall–Olkin Copula Model for Network Reliability Under Dependent Failures

Cited by 20 publications

References 29 publications

Efficient Estimation of Stochastic Flow Network Reliability

Efficient Estimation of Stochastic Flow Network Reliability

Limit distributions of the upper order statistics for the Lévy-frailty Marshall-Olkin distribution

Communication Network Reliability under geographically correlated failures using Probabilistic Seismic Hazard Analysis

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