Intelligent Optimization Under Multiple Factories: Hybrid Flow Shop Scheduling Problem with Blocking Constraints Using an Advanced Iterated Greedy Algorithm

Yong Wang;Yuting Wang;Yuyan Han;Junqing Li;Kaizhou Gao;Yusuke Nojima
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Abstract

The distributed hybrid flow shop scheduling problem (DHFSP), which integrates distributed manufacturing models with parallel machines, has gained significant attention. However, in actual scheduling, some adjacent machines do not have buffers between them, resulting in blocking. This paper focuses on addressing the DHFSP with blocking constraints (DBHFSP) based on the actual production conditions. To solve DBHFSP, we construct a mixed integer linear programming (MILP) model for DBHFSP and validate its correctness using the Gurobi solver. Then, an advanced iterated greedy (AIG) algorithm is designed to minimize the makespan, in which we modify the Nawaz, Enscore, and Ham (NEH) heuristic to solve blocking constraints. To balance the global and local search capabilities of AIG, two effective inter-factory neighborhood search strategies and a swap-based local search strategy are designed. Additionally, each factory is mutually independent, and the movement within one factory does not affect the others. In view of this, we specifically designed a memory-based decoding method for insertion operations to reduce the computation time of the objective. Finally, two shaking strategies are incorporated into the algorithm to mitigate premature convergence. Five advanced algorithms are used to conduct comparative experiments with AIG on 80 test instances, and experimental results illustrate that the makespan and the relative percentage increase (RPI) obtained by AIG are 1.0% and 86.1% respectively, better than the comparative algorithms.
多工厂下的智能优化:使用高级迭代贪婪算法解决带阻塞约束的混合流水车间调度问题
分布式混合流水车间调度问题(DHFSP)将分布式制造模型与并行机器整合在一起,受到了广泛关注。然而,在实际调度中,一些相邻机器之间没有缓冲区,从而导致堵塞。本文基于实际生产条件,重点解决了带阻塞约束的 DHFSP(DBHFSP)问题。为了解决 DBHFSP,我们构建了 DBHFSP 的混合整数线性规划(MILP)模型,并使用 Gurobi 求解器验证了其正确性。然后,我们设计了一种高级迭代贪婪(AIG)算法来最小化有效期,其中我们修改了 Nawaz、Enscore 和 Ham(NEH)启发式来解决阻塞约束。为了平衡 AIG 的全局和局部搜索能力,我们设计了两种有效的工厂间邻域搜索策略和一种基于交换的局部搜索策略。此外,每个工厂都是相互独立的,一个工厂内的移动不会影响其他工厂。有鉴于此,我们专门为插入操作设计了一种基于内存的解码方法,以减少目标的计算时间。最后,我们在算法中加入了两种震动策略,以减少过早收敛。我们使用五种先进算法在 80 个测试实例上与 AIG 进行了对比实验,实验结果表明,AIG 所获得的时间跨度(makespan)和相对百分比增长(RPI)分别为 1.0% 和 86.1%,优于其他算法。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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