Abstract
A device that performs its intended function only once is referred to as a one-shot device. Actual lifetimes of such kind of devices under test cannot be observed, and they are either left-censored or right-censored. In addition, one-shot devices often consist of multiple components that could cause the failure of the device. The components are coupled together in the manufacturing process or assembly, resulting in the failure modes possessing latent heterogeneity and dependence. In this paper, we develop an efficient expectation–maximization algorithm for determining the maximum likelihood estimates of model parameters, on the basis of one-shot device test data with multiple failure modes under a constant-stress accelerated life-test, with the dependent components having exponential lifetime distributions under gamma frailty that facilitates an easily understandable interpretation. The maximum likelihood estimate and confidence intervals for the mean lifetime of k-out-of-M structured one-shot device under normal operating conditions are also discussed. The performance of the proposed inferential methods is finally evaluated through Monte Carlo simulations. Three examples including Class-H failure modes data, mice data from ED01 experiment, and simulated data with four failure modes are used to illustrate the proposed inferential methods.
Highlights
A one-shot device is a device that is destroyed after its use, and so the device intends to perform its function only once
The results show that the likelihood ratio test (LRT) outperforms the asymptotic confidence interval (ACI) method for identifying the dependence between components when the component lifetimes are dependent, but the LRT does possess a higher probability of type I
We have developed an efficient EM algorithm that provides a stable and robust method for finding the maximum likelihood estimates (MLEs) of model parameters for a k-out-of-M structured oneshot device with dependent components having exponential lifetime distribution under gamma frailty to capture the dependence
Summary
A one-shot device is a device that is destroyed after its use, and so the device intends to perform its function only once. Balakrishnan et al [19] presented competing-risks models for analyzing one-shot device test data with failure modes for Weibull lifetime distributions. In these studies, the considered models assume independence between failure modes. Ling et al [23] recently investigated one-shot device test data under two popular copula models and demonstrated that oneshot devices with positively dependent failure modes result in longer lifetimes than those with independent failure modes.
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