Parâmetros Imunológicos E Infecções Do Trato Respiratório Superior Em Atletas De Esportes Coletivos

A formal approach to produce a model for the data-generating distribution based on partial knowledge is the well-known maximum entropy method. In this approach, partial knowledge about the data-generating distribution is formulated in terms of some information constraints and the model is obtained by maximizing the Shannon entropy under these constraints. Frequently, in reliability analysis the problem of interest is the lifetime beyond an age t. In such cases, the distribution of interest for computing uncertainty and information is the residual distribution. The information functions involving a residual life distribution depend on t, and hence are dynamic. The maximum dynamic entropy (MDE) model is the distribution with the density that maximizes the dynamic entropy for all t. We provide a result that relates the orderings of dynamic entropy and the hazard function for distributions with monotone densities. Applications include dynamic entropy ordering within some parametric families of distributions, orderings of distributions of lifetimes of systems and their components connected in series and parallel, record values, and formulation of constraints for the MDE model in terms of the evolution paths of the hazard function and mean residual lifetime function. In particular, we identify classes of distributions in which some well-known distributions, including the mixture of two exponential distributions and the mixture of two Pareto distributions, are the MDE models.

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A Note on the Mean Residual Life Function of a Parallel System

Asadi

Bayramoğlu

2005

Communications in Statistics - Theory and Methods

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Dynamic Reliability Modeling of Three-State Networks

Ashrafi¹,

Asadi²

2014

J. Appl. Probab.

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This paper is an investigation into the reliability and stochastic properties of three-state networks. We consider a single-step network consisting of n links and we assume that the links are subject to failure. We assume that the network can be in three states, up (K = 2), partial performance (K = 1), and down (K = 0). Using the concept of the two-dimensional signature, we study the residual lifetimes of the networks under different scenarios on the states and the number of failed links of the network. In the process of doing so, we define variants of the concept of the dynamic signature in a bivariate setting. Then, we obtain signature based mixture representations of the reliability of the residual lifetimes of the network states under the condition that the network is in state K = 2 (or K = 1) and exactly k links in the network have failed. We prove preservation theorems showing that stochastic orderings and dependence between the elements of the dynamic signatures (which relies on the network structure) are preserved by the residual lifetimes of the states of the network (which relies on the network ageing). Various illustrative examples are also provided.

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Dynamic generalized information measures

Asadi

Ebrahimi

Soofi

2005

Statistics & Probability Letters

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Majid Asadi

On the dynamic cumulative residual entropy

Some new results on the cumulative residual entropy

On the mean past lifetime of the components of a parallel system

The Mean Residual Life Function of a<tex>$k$</tex>-out-of-<tex>$n$</tex>Structure at the System Level

Maximum dynamic entropy models

A Note on the Mean Residual Life Function of a Parallel System

Dynamic Reliability Modeling of Three-State Networks

Dynamic generalized information measures

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