Myopic Strategy for Dynamic Scheduling of Printed Circuit Board Drilling Tasks

doi:10.3969/j.issn.1007-7375.2021.06.003

Abstract

Abstract: The scheduling of printed circuit board drilling tasks is difficult due to stochastic arrivals and process requirements. Considering the NP-hard property of the problem, myopic strategies based on priority rule and intelligent algorithm are proposed. In these strategies, an event-driven rescheduling mechanism is used to trigger the optimization algorithm on task arrival and task completion, which makes decisions on current unstarted tasks. In order to solve the optimization problem at each decision time point efficiently, a simulated annealing algorithm and a variable neighborhood search algorithm embedded with local dominance rules are constructed. The initial solutions of these algorithms are obtained by priority rules. Computational experiments are conducted to compare the proposed intelligent algorithms with classic priority rules under different scheduling environments. Experimental results show that the optimization effect of intelligent algorithms under most objectives is improved by more than 20% compared with the priority rules. The optimization effect of variable neighborhood search is slightly better than that of simulated annealing, but the latter is twice as efficient.

Key words: printed circuit board, drilling tasks, dynamic scheduling, myopic strategy, simulated annealing, variable neighborhood search

CLC Number:

TP391

YAN Minjie, WANG Xiaoming, ZHU Songping, CHEN Qingxin, MAO Ning. Myopic Strategy for Dynamic Scheduling of Printed Circuit Board Drilling Tasks[J]. Industrial Engineering Journal, 2021, 24(6): 18-24,56.

References

[1] XING W, ZHANG J. Parallel machine scheduling with splitting jobs[J]. Discrete Applied Mathematics, 2000, 103(1): 259-269
[2] KIM Y D, SHIM S O, KIM S B, et al. Parallel machine scheduling considering a job-splitting property[J]. International Journal of Production Research, 2004, 42(21): 4531-4546
[3] SHIM S O, KIM Y D. A branch and bound algorithm for an identical parallel machine scheduling problem with a job splitting property[J]. Computers & Operations Research, 2008, 35(3): 863-875
[4] SARIÇIÇEK İ, ÇELIK C. Two meta-heuristics for parallel machine scheduling with job splitting to minimize total tardiness[J]. Applied Mathematical Modelling, 2011, 35(8): 4117-4126
[5] KIM J G, SONG S, JEONG B. Minimising total tardiness for the identical parallel machine scheduling problem with splitting jobs and sequence-dependent setup times[J]. International Journal of Production Research, 2020, 58(6): 1628-1643
[6] YALAOUI F, CHU C. An efficient heuristic approach for parallel machine scheduling with job splitting and sequence-dependent setup times[J]. IIE Transactions, 2003, 35(2): 183-190
[7] NAIT TAHAR D, YALAOUI F, CHU C, et al. A linear programming approach for identical parallel machine scheduling with job splitting and sequence-dependent setup times[J]. International Journal of Production Economics, 2006, 99(1): 63-73
[8] WANG W L, WANG H Y, ZHAO Y W, et al. Parallel machine scheduling with splitting jobs by a hybrid differential evolution algorithm[J]. Computers & Operations Research, 2013, 40(5): 1196-1206
[9] WANG C, LIU C, ZHANG Z H, et al. Minimizing the total completion time for parallel machine scheduling with job splitting and learning[J]. Computers & Industrial Engineering, 2016, 97: 170-182
[10] LIU C, WANG C, ZHANG Z H, et al. Scheduling with job-splitting considering learning and the vital-few law[J]. Computers & Operations Research, 2018, 90: 264-274
[11] LIANG Y C, HSIAO Y M, TIEN C Y. Metaheuristics for drilling operation scheduling in Taiwan PCB industries[J]. International Journal of Production Economics, 2013, 141(1): 189-198
[12] OUELHADJ D, PETROVIC S. A survey of dynamic scheduling in manufacturing systems[J]. J Sched, 2009, 12(4): 417-431
[13] AYTUG H, LAWLEY M A, MCKAY K, et al. Executing production schedules in the face of uncertainties: a review and some future directions[J]. European Journal of Operational Research, 2005, 161(1): 86-110
[14] ÐURASEVIĆ M, JAKOBOVIĆ D. A survey of dispatching rules for the dynamic unrelated machines environment[J]. Expert Systems with Applications, 2018, 113: 555-569
[15] NIE L, GAO L, LI P, et al. A GEP-based reactive scheduling policies constructing approach for dynamic flexible job shop scheduling problem with job release dates[J]. Journal of Intelligent Manufacturing, 2013, 24(4): 763-774
[16] BECK J C, WILSON N. Proactive algorithms for job shop scheduling with probabilistic durations[J]. Journal of Artificial Intelligence Research, 2007, 28: 183-232
[17] RAHMANI D, HEYDARI M. Robust and stable flow shop scheduling with unexpected arrivals of new jobs and uncertain processing times[J]. Journal of Manufacturing Systems, 2014, 33(1): 84-92
[18] CHURCH L K, UZSOY R. Analysis of periodic and event-driven rescheduling policies in dynamic shops[J]. International Journal of Computer Integrated Manufacturing, 1992, 5(3): 153-163
[19] 刘爱军, 杨育, 邢青松, 等. 柔性作业车间多目标动态调度[J]. 计算机集成制造系统, 2011, 17(12): 2629-2637
LIU Aijun, YANG Yu, XING Qingsong, et al. Dynamic scheduling on multi-objective flexible job shop[J]. Computer Integrated Manufacturing Systems, 2011, 17(12): 2629-2637
[20] 来凯, 王小明, 陈庆新, 等. 面向模具项目动态调度问题的优先规则对比研究[J]. 工业工程, 2017, 20(5): 28-37
LAI Kai, WANG Xiaoming, CHEN Qingxin, et al. A comparative study of priority rules on mold project dynamic scheduling problem[J]. Industrial Engineering Journal, 2017, 20(5): 28-37
[21] 王小岗, 王小明, 陈庆新, 等. 具有随机返工且可中断的设计任务调度[J]. 工业工程, 2019, 22(5): 59-67
WANG Xiaogang, WANG Xiaoming, CHEN Qingxin, et al. Preemptive scheduling of design tasks with random rework[J]. Industrial Engineering Journal, 2019, 22(5): 59-67
[22] LAWRENCE S R, MORTON T E. Resource-constrained multi-project scheduling with tardy costs: comparing myopic, bottleneck, and resource pricing heuristics[J]. European Journal of Operational Research, 1993, 64(2): 168-187
[23] HANSEN P, MLADENOVIĆ N. Variable neighborhood search: principles and applications[J]. European Journal of Operational Research, 2001, 130(3): 449-467