改进GWO求解考虑恶化工件的柔性作业车间低碳调度问题

doi:10.3778/j.issn.1002-8331.2409-0193

摘要/Abstract

摘要： 为应对工件恶化的柔性作业车间低碳调度问题，提出了一种改进的灰狼优化算法，旨在减少最大完工时间、降低碳排放并提高加工质量。该算法设计了一种基于升序排列规则（ranked order value， ROV）的三层编码机制，并结合考虑设备空闲时间的新型插入式贪婪解码方法，用于动态优化调度方案构成，提升初始种群质量；提出一种融合交换、逆序、插入与变异四种操作的搜索机制改进灰狼算法迭代过程中易陷入局部最优解的问题；引入正态随机正弦参数策略和自适应惯性权重策略改进种群位置更新机制；结合Brandimarte算例对调度模型进行测试，仿真结果表明，所提算法有效且具有优越性，适用于解决因工件恶化引起的加工偏差问题。

关键词: 柔性作业车间低碳调度, 恶化工件, 灰狼优化算法, 车间调度算例

Abstract: To address the low-carbon scheduling problem of flexible job shops with deteriorating workpieces, an improved grey wolf optimization (GWO) algorithm is proposed. The algorithm aims to minimize the maximum completion time, reduce carbon emissions, and improve processing quality. A three-layer encoding mechanism based on the ranked order value rule is designed, along with a novel insert-type greedy decoding method that took machine idle times into account. This is used for dynamically optimizing the scheduling scheme and improving the quality of the initial population. Then, a search mechanism combining swap, reverse, insertion, and mutation operations is proposed to improve the issue of the grey wolf optimizer easily falling into local optima during iterations. Additionally, a normal random sine parameter strategy and an adaptive inertia weight strategy are introduced to improve the population position update mechanism. Finally, the scheduling model is tested using the Brandimarte benchmark. The simulation results show that the proposed algorithm is effective and superior, making it suitable for addressing processing deviations caused by workpieces deterioration.

Key words: low-carbon scheduling in flexible job shop, deteriorating workpieces, grey wolf optimization algorithm, shop scheduling example

王斌, 武沅铂. 改进GWO求解考虑恶化工件的柔性作业车间低碳调度问题[J]. 计算机工程与应用, 2025, 61(24): 331-345.

WANG Bin, WU Yuanbo. Improved GWO for Solving Low-Carbon Scheduling Problem of Flexible Job Shop Considering Deteriorating Workpieces[J]. Computer Engineering and Applications, 2025, 61(24): 331-345.

参考文献

[1] 郭朝先. 改革开放40年中国工业发展主要成就与基本经验[J]. 北京工业大学学报(社会科学版), 2018, 18(6): 1-11.
GUO C X. Major achievements and basic experience of China’s industrial development in the past 40 years of reform and opening up[J]. Journal of Beijing University of Technology (Social Sciences Edition), 2018, 18(6): 1-11.
[2] 王凌, 王晶晶, 吴楚格. 绿色车间调度优化研究进展[J]. 控制与决策, 2018, 33(3): 385-391.
WANG L, WANG J J, WU C G. Advances in green shop scheduling and optimization[J]. Control and Decision, 2018, 33(3): 385-391.
[3] 李峥峰, 于小忠, 张国辉, 等. 考虑生产过程时间的柔性作业车间调度优化[J]. 工业工程, 2020, 23(2): 26-33.
LI Z F, YU X Z, ZHANG G H, et al. Optimization for the flexible job shop scheduling problems with production process time[J]. Industrial Engineering Journal, 2020, 23(2): 26-33.
[4] 詹欣隆, 张超勇, 孟磊磊, 等. 面向高效低碳的切削参数与柔性作业车间调度集成建模与优化[J]. 计算机集成制造系统, 2021, 27(12): 3519-3535.
ZHAN X L, ZHANG C Y, MENG L L, et al. Integrated optimization of cutting parameters and flexible job shop scheduling based on improved discrete gravity search algorithm[J]. Computer Integrated Manufacturing Systems, 2021, 27(12): 3519-3535.
[5] WANG Z X, HE M W, WU J, et al. An improved MOEA/D for low-carbon many-objective flexible job shop scheduling problem[J]. Computers & Industrial Engineering, 2024, 188: 109926.
[6] LI Y B, HUANG W X, WU R, et al. An improved artificial bee colony algorithm for solving multi-objective low-carbon flexible job shop scheduling problem[J]. Applied Soft Computing, 2020, 95: 106544.
[7] GHORBANI SABER R, RANJBAR M. Minimizing the total tardiness and the total carbon emissions in the permutation flow shop scheduling problem[J]. Computers & Operations Research, 2022, 138: 105604.
[8] 姜一啸, 吉卫喜, 何鑫, 等. 基于改进非支配排序遗传算法的多目标柔性作业车间低碳调度[J]. 中国机械工程, 2022, 33(21): 2564-2577.
JIANG Y X, JI W X, HE X, et al. Low-carbon scheduling of multi-objective flexible job-shop based on improved NSGA-Ⅱ[J]. China Mechanical Engineering, 2022, 33(21): 2564-2577.
[9] 张梓琪, 钱斌, 胡蓉, 等. 基于多维EDA算法的低碳分布式装配流水车间调度[J]. 控制与决策, 2022, 37(5): 1367-1377.
ZHANG Z Q, QIAN B, HU R, et al. Multidimensional estimation of distribution algorithm for low carbon scheduling of distributed assembly permutation flow-shop[J]. Control and Decision, 2022, 37(5): 1367-1377.
[10] 李明, 雷德明. 考虑准备时间和关键目标的柔性作业车间低碳调度研究[J]. 机械工程学报, 2019, 55(21): 139-149.
LI M, LEI D M. Research on flexible job shop low carbon scheduling with setup times and key objectives[J]. Journal of Mechanical Engineering, 2019, 55(21): 139-149.
[11] 朱赟海, 罗陆锋, 卢清华, 等. 面向订单扰动的柔性作业车间动态调度方法[J/OL]. 计算机集成制造系统, 2023: 1-23(2023-02-24)[2024-08-13]. https://kns.cnki.net/kcms/detail/11.5946.TP. 20230223.1654.036.html.
ZHU Y H, LUO L F, LU Q H, et al. Dynamic scheduling method for flexible job shop oriented to order disturbance[J/OL]. Computer Integrated Manufacturing Systems, 2023: 1-23(2023-02-24)[2024-08-13]. https://kns.cnki.net/kcms/detail/11.5946.TP. 20230223.1654.036.html.
[12] 苏建涛, 董绍华, 朱诗敏. 多目标混合流水车间机器故障重调度问题研究[J]. 机械工程学报, 2024, 60(4): 438-448.
SU J T, DONG S H, ZHU S M. Research on machine fault rescheduling problem of multi objective hybrid flow shop based on intelligent manufacturing[J]. Journal of Mechanical Engineering, 2024, 60(4): 438-448.
[13] ZHOU G H, CHEN Z H, ZHANG C, et al. An adaptive ense-mble deep forest based dynamic scheduling strategy for low carbon flexible job shop under recessive disturbance[J]. Journal of Cleaner Production, 2022, 337: 130541.
[14] SCHULZ S, SCH?NHEIT M, NEUFELD J S. Multi-objective carbon-efficient scheduling in distributed permutation flow shops under consideration of transportation efforts[J]. Journal of Cleaner Production, 2022, 365: 132551.
[15] GONG G L, CHIONG R, DENG Q W, et al. Energy-efficient flexible flow shop scheduling with worker flexibility[J]. Expert Systems with Applications, 2020, 141: 112902.
[16] 张洪亮, 徐公杰, 鲍蔷, 等. 考虑运输时间和机器预维护的柔性作业车间绿色调度[J]. 计算机集成制造系统, 2024, 30(9): 3111-3124.
ZHANG H L, XU G J, BAO Q, et al. Flexible job-shop green scheduling considering transportation time and machine preventive maintenance[J]. Computer Integrated Manufacturing Systems, 2024, 30(9): 3111-3124.
[17] 轩华, 赵凤娟, 李冰. 带线性恶化工件的零等待流水车间调度[J]. 控制工程, 2021, 28(12): 2305-2311.
XUAN H, ZHAO F J, LI B. Zero-wait flow shop scheduling with linear deteriorating jobs[J]. Control Engineering of China, 2021, 28(12): 2305-2311.
[18] 孟冠军, 黄江涛, 魏亚博. 混合白鲸优化算法求解柔性作业车间调度问题[J]. 计算机工程与应用, 2024, 60(12): 325-333.
MENG G J, HUANG J T, WEI Y B. Hybrid beluga whale optimization algorithm for flexible job shop scheduling problem[J]. Computer Engineering and Applications, 2024, 60(12): 325-333.
[19] 张雷, 赵希坤, 蒋诗新, 等. 低碳低成本约束下箱体零件加工路线优化方法[J]. 中国机械工程, 2018, 29(23): 2836-2844.
ZHANG L, ZHAO X K, JIANG S X, et al. Optimization method of process routes for housing parts under low-carbon and low-cost constraints[J]. China Mechanical Engineering, 2018, 29(23): 2836-2844.
[20] 姜志鹏. 数控切削加工过程碳排放优化及绿色性评价方法研究[D]. 哈尔滨: 哈尔滨工业大学, 2020.
JIANG Z P. Research on carbon emission optimization and greenness evaluation method in CNC machining process[D]. Harbin: Harbin Institute of Technology, 2020.
[21] BRANDIMARTE P. Routing and scheduling in a flexible job shop by tabu search[J]. Annals of Operations Research, 1993, 41(3): 157-183.
[22] NARITA H, FUJIMOTO H. Analysis of environmental impact due to machine tool operation[J]. International Journal of Automation Technology, 2009, 3(1): 49-55.
[23] 王丽萍, 任宇, 邱启仓, 等. 多目标进化算法性能评价指标研究综述[J]. 计算机学报, 2021, 44(8): 1590-1619.
WANG L P, REN Y, QIU Q C, et al. Survey on performance indicators for multi-objective evolutionary algorithms[J]. Chinese Journal of Computers, 2021, 44(8): 1590-1619.
[24] IBRAHIM A M, TAWHID M A. An improved artificial algae algorithm integrated with differential evolution for job-shop scheduling problem[J]. Journal of Intelligent Manufacturing, 2023, 34(4): 1763-1778.
[25] 张安, 杨咪, 毕文豪, 等. 基于多策略GWO算法的不确定环境下异构多无人机任务分配[J]. 航空学报, 2023, 44(8): 148-164.
ZHANG A, YANG M, BI W H, et al. Task allocation of heterogeneous multi-UAVs in uncertain environment based on multi-strategy integrated GWO[J]. Acta Aeronautica et Astronautica Sinica, 2023, 44(8): 148-164.
[26] SALIDO M A, ESCAMILLA J, GIRET A, et al. A genetic algorithm for energy-efficiency in job-shop scheduling[J]. The International Journal of Advanced Manufacturing Technology, 2016, 85(5): 1303-1314.