Advances in Stochastic Models for Reliablity, Quality and Safety

Fast technological development produces systems of ever-increasing complex ity. The demand for reliable functioning of these systems has become more and more important. Thus, there is a need for highly reliable technical devices and systems, for monitoring and controlling their functioning and for planning maintenance and corrective actions to fulfill given requirements considering eco nomic limitations. These tasks reflect the wide field of engineering activities that are accompa nied by and based on a wide range of stochastical models. The book presents the main contributions to a workshop on Stochastic Models of Reliability, Qual ity, and Safety held in Schierke near Magdeburg, Germany. This workshop was part of a series of meetings that take place every two years organized by the Society of Reliability, Quality and Safety. The basic idea of these workshops is to bring together theorists, applied statisticians, and practitioners to exchange experiences and ideas of common interest. The book contains recent results in reliability and related fields. The presentation aims at making at least a part of the results accessible to engineers.

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Fast technological development produces systems of ever-increasing complex­ ity. The demand for reliable functioning of these systems has become more and more important. Thus, there is a need for highly reliable technical devices and systems, for monitoring and controlling their functioning and for planning maintenance and corrective actions to fulfill given requirements considering eco­ nomic limitations. These tasks reflect the wide field of engineering activities that are accompa­ nied by and based on a wide range of stochastical models. The book presents the main contributions to a workshop on Stochastic Models of Reliability, Qual­ ity, and Safety held in Schierke near Magdeburg, Germany. This workshop was part of a series of meetings that take place every two years organized by the Society of Reliability, Quality and Safety. The basic idea of these workshops is to bring together theorists, applied statisticians, and practitioners to exchange experiences and ideas of common interest. The book contains recent results in reliability and related fields. The presentation aims at making at least a part of the results accessible to engineers.

Contenu
I: Lifetime Analysis.- 1. The Generalized Linnik Distributions.- 1.1 Introductory Example and Preliminaries.- 1.2 Assembling Discrete Linnik and Discrete Stable Distributions.- 1.3 Calculation of Probabilities.- 1.4 Characterization via Survival Distributions.- 1.5 Asymptotic Behaviour.- References.- 2. Acceptance Regions and Their Application in Lifetime Estimation.- 2.1 Confidence Bounds Based on Acceptance Regions.- 2.1.1 Basic notations.- 2.1.2 Confidence bound and system of acceptance regions.- 2.1.3 The algorithm System of lower ?-acceptance regions.- 2.1.4 Quality of lower confidence bounds.- 2.1.5 Optimality of the algorithm.- 2.1.6 Quick determination vs. good quality.- 2.2 Confidence Bound for the Expectation of a Weibull Distribution.- 2.2.1 The model.- 2.2.2 Applying the algorithm System of lower ?-acceptance regions.- 2.2.3 Quality of lower confidence bounds for the expectation.- References.- 3. On Statistics in Failure-Repair Models Under Censoring.- 3.1 Introduction.- 3.2 Survival Data Analysis Under Censoring.- 3.3 Nonparametric Estimators for RT(t).- 3.4 The Failure-Repair Model Under Censoring.- 3.4.1 The general model.- 3.4.2 Model under Koziol-Green assumption.- References.- 4. Parameter Estimation in Renewal Processes with Imperfect Repair.- 4.1 Introduction.- 4.2 A General Model.- 4.3 Specifications.- 4.4 Parameter Estimation in the General Model.- 4.4.1 Estimation of the parameters of failure intensity.- 4.4.2 A simple model for estimating the degree of repair.- References.- 5. Investigation of Convergence Rates in Risk Theory in the Presence of Heavy Tails.- 5.1 A Model in Risk Theory.- 5.2 Limit Theorem.- 5.3 Rates of Convergence.- References.- 6. Least Squares and Minimum Distance Estimation in the Three-Parameter Weibull and Fréchet Models with Applications to River Drain Data.- 6.1 Introduction.- 6.2 Least Squares and Minimum Distance Methods.- 6.2.1 General.- 6.2.2 Least squares and minimum distance estimators for the three-parameter Weibull model.- 6.3 Modelling of River Drain Data.- 6.3.1 The data.- 6.3.2 General.- 6.3.3 Analysis of river Danube data.- 6.3.4 Analysis of river Main data.- References.- II: Reliability Analysis.- 7. Maximum Likelihood Estimation With Different Sequential k-out-of-n Systems.- 7.1 Introduction.- 7.2 Sequential k-out-of-n Systems With Unknown Model Parameters.- 7.3 Estimation in Specific Distributions.- 7.4 Sequential k-out-of-n Systems With Known Model Parameters and Underlying One-Parameter Exponential Family.- 7.5 Example: Sequential 2-out-of-4 System.- References.- 8. Stochastic Models for the Return of Used Devices.- 8.1 Introduction.- 8.2 Additive Models for Returns.- 8.3 Model Fit.- References.- 9. Some Remarks on Dependent Censoring in Complex Systems.- 9.1 Introduction and Summary.- 9.2 Dependence of the Components Within a Parallel System.- 9.2.1 Estimation of F by means of Fjk.- 9.2.2 Estimation of F by means of the Kaplan-Meier estimators of Fj.- 9.2.3 Estimation of F by means of multivariate Kaplan-Keier estimators.- 9.3 Dependence of the Lifelengths and their Censoring Variables.- References.- 10. Parameter Estimation in Damage Processes: Dependent Observations of Damage Increments and First Passage Time.- 10.1 Introduction.- 10.2 The Likelihood Function if Both Damage Increments and Failure Time are Observed.- 10.3 An Example.- 10.4 Appendix: Proof of Lemma 10.2.1.- References.- 11. Boundary Crossing Probabilities of Poisson Counting Processes with General Boundaries.- 11.1 Introduction.- 11.2 The Homogeneous Poisson Process.- 11.2.1 Upper boundary case.- 11.2.2 Lower boundary case.- 11.2.3 Two boundary case.- 11.3 The Nonhomogeneous Poisson Process.- 11.4 A Special Mixed Poisson Process.- References.- 12. Optimal Sequential Estimation for Markov-Additive Processes.- 12.1 Introduction.- 12.2 The Model and Sampling Times.- 12.3 Efficient Sequential Procedures.- 12.4 Minimax Sequential Procedures.- References.- 13. Some Models Describing Damage Processes and Resulting First Passage Times.- 13.1 Introduction.- 13.2 Basic Definitions.- 13.3 System Failure Time in the Case of Independent Marking.- 13.3.1 ML-Estimates for parameters in the distribution of the system failure time.- References.- 14. Absorption Probabilities of a Brownian Motion in a Triangular Domain.- 14.1 Introduction.- 14.2 A Random Walk Result and Some Used Limit Theorems.- 14.3 The Case of Equal Drifts.- 14.4 The Case of Opposite Drifts.- 14.5 Discussion of the Results.- References.- III: Network Analysis.- 15. A Simple Algorithm for Calculating Approximately the Reliability of Almost Arbitrary Large Networks.- 15.1 Introduction.- 15.2 Notations.- 15.3 The Approximation.- 15.3.1 Simple network.- 15.4 Algorithms.- 15.4.1 Compound system.- 15.5 Accuracy.- 15.5.1 Example 1: Network ARTI.- 15.5.2 Example 2: Network K6.- 15.5.3 Example 3: Network K7.- 15.5.4 Example 4: Network ALG.- 15.5.5 Example 5: LGR.- 15.5.6 Example 6: Network EVA.- 15.5.7 Example 7: Network DGN.- 15.5.8 Example 8: FNW.- 15.5.9 Example 9: Network TECL.- 15.5.10 Example 10: Network RCG.- 15.6 Conclusions.- References.- 16. Reliability Analysis of Flow Networks.- 16.1 Introduction.- 16.2 List of Used Symbols.- 16.3 Definitions.- 16.4 Flow Probability.- 16.5 Computation of the Flow Probability.- 16.5.1 The decomposition algorithm.- 16.5.2 Special values of the demanded flow.- 16.5.3 Special structures.- 16.5.4 Computation by a generating function.- References.- 17. Generalized Gram-Charlier Series A and C Approximation for Nonlinear Mechanical Systems.- 17.1 Introduction.- 17.2 Formulation of the Problem.- 17.3 Generalized Gram-Ch…