Time-Cost Tradeoff Optimization for Scheduling Repetitive Projects with Fuzzy Activity Durations

doi:10.3969/j.issn.1007-7375.230104

Abstract

Abstract: In order to reduce the impact of uncertainty on project performance objectives and improve the robustness of scheduling, the discrete time-cost tradeoff problem for repetitive projects with fuzzy activity durations is investigated. A fuzzy chance-constrained programming model considering the risk preferences of decision makers is developed by means of fuzzy risk measurement to determine the optimal execution modes for all activities (i.e., mode list), thereby to minimize the project budget while meeting the pre-speci?ed risk levels of project delays and cost overruns. Given a known mode list, a forward recursive process for calculating the membership functions of fuzzy project duration and fuzzy total cost is proposed, while an improved genetic algorithm based on electromagnetic mechanism (GA-EM) for searching the optimal mode list is designed accordingly. The effectiveness of the algorithm is veri?ed using a real-life engineering case, and the computational performance of the algorithm is analyzed via numerical experiments. Results show that GA-EM can provide a fuzzy schedule that satisfies the given levels of schedule delays and cost overrun risks, with the average and maximum percentage deviations in the budget not exceeding 0.096% and 0.239%, respectively.

Key words: time-cost tradeoff, repetitive projects, fuzzy chance-constrained programming, genetic algorithm

CLC Number:

F402
N949

ZOU Xin, CHEN Danhao, ZHANG Lihui. Time-Cost Tradeoff Optimization for Scheduling Repetitive Projects with Fuzzy Activity Durations[J]. Industrial Engineering Journal, 2024, 27(4): 150-160,170.

References

[1] EID M S, ELBELTAGI E E, EL-ADAWAY I H. Simultaneo-us multi-criteria optimization for scheduling linear infrastructure projects[J]. International Journal of Construction Management, 2021, 21(1): 41-55
[2] ZOU X, FANG S C, HUANG Y S, et al. Mixed-integer linear programming approach for scheduling repetitive projects with time-cost trade-off consideration[J]. Journal of Computing in Civil Engineering, 2017, 31(3): 06016003
[3] ALTUWAIM A, EL-RAYES K. Multiobjective optimization model for planning repetitive construction projects[J]. Journal of Construction Engineering and Management, 2021, 147(7): 04021072
[4] ZOU X, ZHANG L. A constraint programming approach for scheduling repetitive projects with atypical activities considering soft logic[J]. Automation in Construction, 2020, 109: 102990
[5] HEGAZY T, KAMARAH E. Schedule optimization for scat-tered repetitive projects[J]. Automation in Construction, 2022, 133: 104042
[6] ZOU X, ZHANG L H, ZHANG Q. Time-cost optimization in repetitive project scheduling with limited resources[J]. Engineering, Construction and Architectural Management, 2022, 29(2): 669-701
[7] GARCÍA-NIEVES J D, PONZ-TIENDA J L, OSPINA-ALVARADO A, et al. Multipurpose linear programming optimization model for repetitive activities scheduling in construction projects[J]. Automation in Construction, 2019, 105: 102799
[8] TOMCZAK M, JAŚKOWSKI P. New approach to improve general contractor crew's work continuity in repetitive construction projects[J]. Journal of Construction Engineering and Management, 2020, 146(5): 04020043
[9] 马咏, 何正文, 郑维博. 基于柔性资源约束的前摄性项目调度优化研究[J]. 中国管理科学, 2020, 28(7): 220-230
MA Yong, HE Zhengwen, ZHENG Weibo. Research on proactive project scheduling optimization based on flexible resource constraints[J]. Chinese Journal of Management Science, 2020, 28(7): 220-230
[10] 胡雪君, 王建江, 崔南方, 等. 资源转移视角下的RCPSP鲁棒资源分配方法[J]. 系统工程学报, 2020, 35(2): 173-187
HU Xuejun, WANG Jianjiang, CUI Nanfang, et al. RCPSP robust resource allocation method from the perspective of resource transfer[J]. Journal of Systems Engineering, 2020, 35(2): 173-187
[11] 李耀业, 王鹏, 张银博, 等. 物联网技术在项目管理领域研究综述[J]. 建筑经济, 2023, 44(3): 72-78.
LI Yaoye, WANG Peng, ZHANG Yinbo, et al. Research review of IOT technology in the field of project management [J]. Construction Economy, 2023, 44 (3): 72-78.
[12] MARAVAS A, PANTOUVAKIS J P. Fuzzy repetitive scheduling method for projects with repeating activities[J]. Journal of Construction Engineering and Management, 2011, 137(7): 561-564
[13] 张国. 大商务管理体系在基建投资项目中的运用[J]. 建筑经济, 2024, 45(4): 52-56.
ZHANG Guo. Application of big business management system in infrastructure investment projects [J]. Construction Economy, 2024, 45 (4): 52-56.
[14] KATSURAGAWA C M, LUCKO G, ISAAC S, etal. Fuzzy linear and repetitive scheduling for construction projects[J]. Journal of Construction Engineering and Management, 2021, 147(3): 04021002
[15] BAKRY I, MOSELHI O, ZAYED T. Optimized schedulin-g and buffering of repetitive construction projects under uncertainty[J]. Engineering, Construction and Architectural Management, 2016, 23(6): 782-800
[16] SALAMA T, MOSELHI O. Multi-objective optimization for repetitive scheduling under uncertainty[J]. Engineering, Cons- truction and Architectural Management, 2019, 26(7): 1294-1320
[17] ROGHABADI M A, MOSELHI O. Optimized crew selection for scheduling of repetitive projects[J]. Engineering, Construction and Architectural Management, 2021, 28(6): 1517-1540
[18] NGUYEN D T, LE-HOAI L, TARIGAN P B, etal. Trade-off time cost quality in repetitive construction project using fuzzy logic approach and symbiotic organism search algorithm[J]. Alexandria Engineering Journal, 2022, 61(2): 1499-1518
[19] KE H, LIU B. Fuzzy project scheduling problem and its hybrid intelligent algorithm[J]. Applied Mathematical Modelling, 2010, 34(2): 301-308
[20] PONZ-TIENDA J L, PELLICER E, BENLLOCH-MARCO J, et al. The fuzzy project scheduling problem with minimal genera-lized precedence relations[J]. Computer-Aided Civil and Infrastructure Engineering, 2015, 30(11): 872-891
[21] CHEN S P, TSAI M J. Time–cost trade-off analysis of project networks in fuzzy environments[J]. European Journal of Opera- tional Research, 2011, 212(2): 386-397
[22] XIAO J, WU Z, HONG X X, et al. Integration of electrom-agnetism with multi-objective evolutionary algorithms for RCPSP[J]. European Journal of Operational Research, 2016, 251(1): 22-35