论文信息 - AN OFFLINE INSPECTION AND DISPOSITION MODEL INCORPORATING DISCRETE WEIBULL DISTRIBUTION AND MANUFACTURING VARIATION

AN OFFLINE INSPECTION AND DISPOSITION MODEL INCORPORATING DISCRETE WEIBULL DISTRIBUTION AND MANUFACTURING VARIATION

To solve the quality control problem for a batch produced from an unreliable production system, an economic offline inspection and disposition (ID) model was previously proposed where the process is assumed to have a constant failure rate, i.e., a geometric shift distribution. Through setting the proper value of parameters in the ID model, three commonly used policies: cost minimizing, perfect information and zero-defects are readily obtained. To facilitate the adoption of the developed ID model in practical applications, this study investigated the ID model in which two additional features are considered: (i) the process has a non-constant failure rate (NCFR). (ii) A manufacturing variation (MV) in the process exists. Two sets of recursive cost equations are obtained to establish an algorithm for the optimal ID policy of a given production lot. Numerical examples are used to show that MV and/or NCFR have significant effects on the minimum cost. The results also show that it is infeasible to reach the perfect information policy once MV exists, but that the zero-defects policy remains feasible. Finally, a concluding remark is made.

Chih-Hsiung Wang | Chen-Chien Hung

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