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Abstract
Statistically optimal and compromise step-stress accelerated degradation test (ADT) plans are developed under the assumption that the degradation characteristic follows a Wiener process. Compromise plans are provided for the case where the experimenter wants to check the validity of the assumed stress-parameter relationship. Two and three step-stress levels are respectively considered in the statistically optimal and compromise ADT plans. For both types of plans, step-stress level(s) and stress level change time(s) are determined such that the asymptotic variance of the maximum likelihood estimator of the q-th quantile of the lifetime distribution at the use condition is minimized. A distinctive feature of the proposed ADT plans is that the stress level can be changed not only at a measurement time but also between two successive measurement times. This feature allows a more general formulation of the two-step-stress ADT planning problem and more flexible three-step-stress compromise ADT plans. Computational results show that in a statistically optimal ADT plan (with two-step-stress levels) the stress change time always coincides with a measurement time. On the other hand, for a compromise plan the stress level sometimes needs to be changed between two successive measurement times to satisfy certain planning requirements. Using an example, the above planning methods are illustrated, the sensitivity of a plan with respect to the uncertainty in the pre-estimate of a model parameter is assessed, and the proposed step-stress ADTs are compared with the constant-stress ADTs and conventional step-stress ADTs in terms of the sample size and/or total testing time.
Acknowledgements
The authors are grateful to the Editor, an Associate Editor, and reviewers for their valuable comments and suggestions that lead to the improvement of the manuscript.
Disclosure statement
The authors report no conflicts of interest. The authors alone are responsible for the content and writing of this article.
Notes on contributors
Si-Il Sung is a Senior Researcher in the Department of Quality Management Operation at Defense Agency for Technology and Quality in Korea. He received his PhD degree in Industrial & Systems Engineering from Korea Advanced Institute of Science and Technology in 2014. His research interests include reliability and quality engineering.
Bong-Jin Yum is an Emeritus Professor in the Department of Industrial & Systems Engineering at Korea Advanced Institute of Science and Technology. He received his Ph.D. degree in Industrial Engineering from the Ohio State University, USA. He formerly held the position of Advanced Industrial Engineer with Owens-Corning Fiberglas, and taught at Texas Tech University. His research interests are in the areas of reliability engineering, robust design, and statistical process control.