A Multi-Objective Genetic Algorithm Based Integrated System for Determining Kanban Number and Size on a JIT System
In a just-in-time (JIT) system, Kanban number and size represent the inventory level of work-in-process (WIP) or purchasing parts. It is an important issue to determine the feasible Kanban number and size. In this research, an integrated multiple objective genetic algorithm (MOGA) based system is developed to determine the Pareto-optimal Kanban number and size, and is applied in a JIT-oriented manufacturing company to demonstrate its feasibility. In the proposed integrated system, a simulation model is created to simulate the multi-stage JIT production system of the company. Then an experimental design of different Kanban numbers and sizes for different production stages is applied to test the production performances. Based on the experimental design and simulation results, regression models are built to represent the relationships between the Kanban numbers of different production stages and the production performance. These regression models are then used in genetic algorithms to generate the performance for chromosomes. Finally, the proposed multi-objective genetic algorithm (MOGA) based system uses the generalized Parato-based scale independent fitness function (GPSIFF) as the fitness function to evaluate the multiple objectives for chromosomes and used to find the Pareto-optimal Kanban number and size for multiple objectives, i.e., maximizing mean throughput rate and minimizing mean total WIP inventory. A comparison in the performance of the proposed system with that of the current Kanban number demonstrates the feasibility of the proposed system.
MOGA JIT Lean Production Kanban
Tung-Hsu Hou Wei-Chung Hu
Douliou, Yunlin, Taiwan Department of Industrial Engineering and Management, National Yunlin Univers Douliou, Yunlin, TaiwanDepartment of Industrial Engineering and Management, National Yunlin Universi
国际会议
上海
英文
1-6
2009-08-02(万方平台首次上网日期,不代表论文的发表时间)