| Volume 7, Number 1, 2017, Pages 224-235 DOI:10.11948/2017015 |
| An arithmetic-geometric mean inequality approach for determining the optimal production lot size with backlogging and imperfect rework process |
| Chun-Tao Chang,Liang-Yuh Ouyang |
| Keywords:Production, random defective rate, failure in repair, backlogging, arithmetic-geometric mean inequality. |
| Abstract: |
| Some classical studies on economic production quantity (EPQ) models with imperfect production processes have focused on determining the optimal production lot size. However, these models neglect the fact that the total production-inventory costs can be reduced by reworking imperfect items for a relatively small repair and holding cost. To account for the above phenomenon, we take the out of stock and rework into account and establish an EPQ model with imperfect production processes, failure in repair and complete backlogging. Furthermore, we assume that the holding cost of imperfect items is distinguished from that of perfect ones, as well as, the costs of repair, disposal, and shortage are all included in the proposed model. In addition, without taking complex differential calculus to determine the optimal production lot size and backorder level, we employ an arithmetic-geometric mean inequality method to determine the optimal solutions. Finally, numerical examples and sensitivity analysis are analyzed to illustrate the validity of the proposed model. Some managerial insights are obtained from the numerical examples. |
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