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Tseng-Fung Ho
Department of Industrial Engineering and Management, National Chin-Yi University of Technology, Taichung 41170, Taiwan

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Journal article
Published: 26 July 2020 in Symmetry
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In this study, we first analyze the usability of recycling products, and use the fuzzy set method to determine the main impact on recycling items and their corresponding weights by using the Analytic Hierarchy Process (AHP) to identify various impact recycling levels. The Group Decision Supporting System (GDSS) determines the test standards for the recycling rating. It provides a convenient way for recyclers or manufacturers to classify their own products and use fuzzy numbers to select a set of test standards. It can deduce the recovery rate and remanufacturing rate of different recycling processing levels through the Markov chain model to find out the inventory model and total cost. In the numerical analysis, we found that a recycling rate of more than 90% is probably a necessary decision. Since the processing cost of the 100% recovery rate is doubled, the inventory level and total cost will increase with it. Therefore, this study was combined with the reverse logistics method to find the appropriate decision-making strategy and plan, such as the optimal inventory level and recovery rate.

ACS Style

Tseng-Fung Ho; Chi-Chung Lin; Chih-Ling Lin. Using Fuzzy Sets and Markov Chain Method to Carry out Inventory Strategies with Different Recovery Levels. Symmetry 2020, 12, 1226 .

AMA Style

Tseng-Fung Ho, Chi-Chung Lin, Chih-Ling Lin. Using Fuzzy Sets and Markov Chain Method to Carry out Inventory Strategies with Different Recovery Levels. Symmetry. 2020; 12 (8):1226.

Chicago/Turabian Style

Tseng-Fung Ho; Chi-Chung Lin; Chih-Ling Lin. 2020. "Using Fuzzy Sets and Markov Chain Method to Carry out Inventory Strategies with Different Recovery Levels." Symmetry 12, no. 8: 1226.

Journal article
Published: 08 June 2020 in Sustainability
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Assembly is the final process of manufacturing, and a good assembly plan reduces the effect of the tolerance generated in the early stages by the tolerance elimination. In the current assembly lines, the assemblers pick up the workpieces and install them together by the assembly instructions. When the workpieces are oversize or undersize, the product can not be installed correctly. Therefore, the assembler considers the secondary processing to fix the tolerance and then installs them together again. The product could be installed, but the product quality may be reduced by the secondary process. So, we formulate the assembly process as a combinatorial optimization problem, named by the dimensional chain assembly (DCA) problem. Given some workpieces with the corresponding actual size, computing the assembly guidance is the goal of the DCA problem, and the product quality is applied to represent the solution quality. The assemblers follow the assembly guidance to install the products. We firstly prove that the DCA problem is NP-complete and collect the requirements of solving the DCA problem from the implementation perspective: the sustainability, the minimization of computation time, and the guarantee of product quality. We consider solution refinement and the solution property inheritance of the single-solution evolution approach to discover and refine the quality of the assembly guidance. Based on the above strategies, we propose the assembly guidance optimizer (AGO) based on the simulated annealing algorithm to compute the assembly guidance. From the simulation results, the AGO reaches all requirements of the DCA problem. The variance of the computation time and the solution quality is related to the problem scale linearly, so the computation time and the solution quality can be estimated by the problem scale. Moreover, increasing the search breadth is unnecessary for improving the solution quality. In summary, the proposed AGO satisfies with the necessaries of the sustainability, the minimization of computation time, and the guarantee of product quality for the requirements of the DCA, and it can be considered in the real-world applications.

ACS Style

Chen-Kun Tsung; Tseng-Fung Ho; Hsuan-Yu Huang; Shu-Hui Yang; Po-Nien Tsou; Ming-Cheng Tsai; Yi-Ping Huang. Computing the Assembly Guidance for Maximizing Product Quality in the Virtual Assembly. Sustainability 2020, 12, 4690 .

AMA Style

Chen-Kun Tsung, Tseng-Fung Ho, Hsuan-Yu Huang, Shu-Hui Yang, Po-Nien Tsou, Ming-Cheng Tsai, Yi-Ping Huang. Computing the Assembly Guidance for Maximizing Product Quality in the Virtual Assembly. Sustainability. 2020; 12 (11):4690.

Chicago/Turabian Style

Chen-Kun Tsung; Tseng-Fung Ho; Hsuan-Yu Huang; Shu-Hui Yang; Po-Nien Tsou; Ming-Cheng Tsai; Yi-Ping Huang. 2020. "Computing the Assembly Guidance for Maximizing Product Quality in the Virtual Assembly." Sustainability 12, no. 11: 4690.

Journal article
Published: 08 April 2020 in Mathematics
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This study develops an integrated supplier–remanufacturer and customer (downstream manufacturer) inventory model that takes into account three-echelon system with correlated demands and remanufacturing products allowing a backorder goods condition. This paper improves the observable fact that the first model system customer might select two sources from remanufactured products or supplier products without defective items. The second model further considers the defective items during the screening duration. The results are examined analytically and numerically to show that the policy of single shipment in large lot sizes results in less total cost than a frequent shipments policy. We also explore the impact of recovery rate on the economic benefits of the inventory system. In addition, we also perform sensitivity analysis to study the impact of seven important parameters (transportation cost, recovery rate, screening rate, annual demand, defect rate, and backorder rate, holding cost,) on the optimal solution. Management insights were also discussed.

ACS Style

Tseng-Fung Ho; Chi-Chung Lin; Chih-Ling Lin. Determining the Optimal Inventory and Number of Shipments for a Two-Resource Supply Chain with Correlated Demands and Remanufacturing Products Allowing Backorder. Mathematics 2020, 8, 548 .

AMA Style

Tseng-Fung Ho, Chi-Chung Lin, Chih-Ling Lin. Determining the Optimal Inventory and Number of Shipments for a Two-Resource Supply Chain with Correlated Demands and Remanufacturing Products Allowing Backorder. Mathematics. 2020; 8 (4):548.

Chicago/Turabian Style

Tseng-Fung Ho; Chi-Chung Lin; Chih-Ling Lin. 2020. "Determining the Optimal Inventory and Number of Shipments for a Two-Resource Supply Chain with Correlated Demands and Remanufacturing Products Allowing Backorder." Mathematics 8, no. 4: 548.