Abstract
An objective Bayesian method for the Tweedie Exponential Dispersion (TED) process model is proposed in this paper. The TED process is a generalized stochastic process, including some famous stochastic processes (e.g., Wiener, Gamma, and Inverse Gaussian processes) as special cases. This characteristic model of several types of process, to be more generic, is of particular use for degradation data analysis. At present, the estimation methods of the TED model are the subjective Bayesian method or the frequentist method. However, some products may not have historical information for reference and the sample size is small, which will lead to a dilemma for the frequentist method and subjective Bayesian method. Therefore, we propose an objective Bayesian method to analyze the TED model. Furthermore, we prove that the corresponding posterior distributions have nice properties and propose Metropolis–Hastings algorithms for the Bayesian inference. To illustrate the applicability and advantages of the TED model and objective Bayesian method, we compare the objective Bayesian estimates with the subjective Bayesian estimates and the maximum likelihood estimates according to Monte Carlo simulations. Finally, a case of GaAs laser data is used to illustrate the effectiveness of the proposed methods.
Highlights
With today’s advanced technology, most products are highly reliable
This paper aims to develop an objective Bayesian method for the Tweedie Exponential Dispersion (TED) process model: compared with the existing work, the major contribution of this paper lies in the following three aspects: (1) Noninformative priors, including Jeffreys prior and the reference prior, are provided, which solves the problem of how to choose an appropriate prior for the TED model without historical data in small samples; (2) The proposed priors are proven to have proper posterior distributions and probability matching properties; and
The performances of the confidence intervals for the objective Bayesian method are compared with the asymptotic confidence intervals (ACIs) and subjective Bayesian method in terms of width of confidence interval (WCI) and coverage probability (CP)
Summary
Bayesian analysis for the differential entropy of the Weibull distribution. G.; Fouskakis, D.; Liseo, B.; Ntzoufras, I. J.M. Reference Posterior Distributions for Bayesian Inference. In Handbook of Statistics; Elsevier: Amsterdam, The Netherlands, 2005; Volume 25, pp. B.L.; Peers, H.W. On Formulae for Confidence Points Based on Integrals of Weighted Likelihoods. Noninformative Priors for One Parameter of Many. Posterior Properties of the Nakagami-m Distribution Using Noninformative Priors and Applications in Reliability. W.Q.; Escobar, L.A. Statistical Methods for Reliability Data; Wiley: New York, NY, USA, 1998. Inverse Gaussian Processes With Random Effects and Explanatory Variables for Degradation Data.
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