基于活动重要性的关键链项目综合缓冲监控

doi:10.16381/j.cnki.issn1003-207x.2020.0718

摘要/Abstract

摘要： 为使项目监控重点更加突出和决策信息更加全面，本文提出了一种基于活动重要性的综合缓冲监控方法。新方法引入了项目进度风险分析方法中的活动重要性信息，结合活动持续时间的波动程度对重要性判断阀值进行了动态设置，对落入项目风险模糊区的重点活动进行识别和监控，综合分析了项目缓冲消耗和后续执行趋势，并根据缓冲监控触发点和缓冲偏差度对项目进度进行控制。实验结果表明，本文方法在监控区域频数分布、缓冲消耗率、项目工期和成本方面的结果更优，克服了现有监控方法的不足，实现了项目计划与进度调整之间的动态反馈，提高了缓冲管理的效率。

关键词: 关键链；缓冲管理；缓冲监控；缓冲后续趋势信息；活动重要性

Abstract: Project delay and cost overrun have been common in all industries nowadays. In order to solve these problems, an effective method—critical chain project management (CCPM) is proposed based on the theory of constraints. It is well known that managers will add a large amount of safety time to the project plan. However, this safety time will be consumed during the implementation of the project owing to various factors, such as the student syndrome, which contribute to the project being delayed and increase project costs. CCPM accordingly adopts the concept of buffer to absorb the uncertainties. As one of the core aspects of buffer management, buffer monitoring plays an important role in ensuring the on-time delivery and providing the project with sufficient protection. Although CCPM has improved the efficiency of project management, project duration delay and cost waste still exist due to the unreasonable buffer monitoring procedure. To deal with the problem that the monitoring focus of existing methods is not prominent and the decision information is not comprehensive in the process of buffer monitoring, an integrated buffer monitoring method based on the important characteristics of the activity is proposed in this paper. First, the new method introduces the activity importance information in the project schedule risk analysis method as a basis for identifying those critical activities that needs more attention and stronger actions. The activity importance of the project is measured by comprehensively considering the variability of the activity's duration, the impact of the activity's duration on the completion of the project, and the network location of the activity. And the judgment threshold of the importance index is dynamically set according to the fluctuation degree of the activity duration. Then, the subsequent trend of buffer consumption was forecasted quantitatively based on gray neural network. Considering the project buffer consumption and project follow-up information comprehensively, the degree of deviation of the buffer consumption state is described by the membership function, corrective actions are differentiated for the activity according to the buffer deviation degree. Meanwhile, the buffer monitoring areas and the action threshold of buffer consumption are set during the dynamic project execution. Finally, the computational experiment based on YS company’s smart party building software development project is carried out to validate our model. The results show that the proposed method can control the progress of the project comprehensively and systematically compared with the traditional monitoring methods. It has better performance in indicators such as monitoring the regional frequency distribution, buffer consumption rate, actual project duration and cost performance, thus realizes the dynamic feedback between project planning and schedule adjustment and improves the efficiency of buffer management. Our research will help scholars better to understand the essence of activity criticality and subsequent trend information in buffer monitoring process, and provide guiding strategies for enterprises to improve the performance of project schedule management and ensure the on-time delivery of projects.

Key words: critical chain; buffer management; buffer monitoring and control; buffer subsequent trend information; activity criticality

中图分类号:

F272

张俊光,万丹. 基于活动重要性的关键链项目综合缓冲监控[J]. 中国管理科学, 2023, 31(4): 79-88.

ZHANG Jun-guang,WAN Dan. Integrated Buffer Monitoring and Control Based on Activity Criticality[J]. Chinese Journal of Management Science, 2023, 31(4): 79-88.

参考文献

［1］ Herroelen W, Leus R, Demeulemeester E. Critical chain project scheduling-Do not oversimplify［J］. Project Management Journal, 2002, 33(4): 46-60.
［2］田旻, 张光军, 刘人境. 基于改进关键链方法的MRCPSP的鲁棒性优化［J］. 系统工程学报, 2019, 152(2): 135-146.Tian Min, Zhang Guangjun, Liu Renjing. Robust optimization of the MRCPSP based on improved critical chain method［J］. Journal of Systems Engineering, 2019, 152(2): 135-146.
［3］张俊光, 万丹. 基于多项目双重风险共担的鼓缓冲设置研究［J］. 运筹与管理, 2021, 30(2), 218-224.Zhang Junguang, Wan Dan. Research on drum buffer sizing based on double risk-pooling of multi-project system［J］. Operations Research and Management Science, 2021, 30(2), 218-224.
［4］ Zhang Junguang, Song Xiwei, Díaz E. Project buffer sizing of a critical chain based on comprehensive resource tightness［J］. European Journal of Operational Research, 2016, 248(1):174-182.
［5］ Zarghami A, Gunawan I, Zubielqui D, et al. Incorporation of resource reliability into critical chain project management buffer sizing［J］. International Journal of Production Research, 2020, 58(20): 6130-6144.
［6］ Long L D, Ohsato A. Fuzzy critical chain method for project scheduling under resource constraints and uncertainty［J］. International Journal of Project Management, 2008, 26(6): 688-698.
［7］ Zhang Junguang, Song Xiwei, Chen Hongyu, et al. Determination of critical chain project buffer based on information flow interactions［J］. Journal of the Operational Research Society, 2016, 67(9):1146-1157.
［8］ Gutierrez G, Paul A. Analysis of the effects of uncertainty, risk-pooling, and subcontracting mechanisms on project performance［J］. Operations Research, 2000, 48(6): 927-938.
［9］ Goldratt E M. Critical chain［M］. Great Barrington, Mass, USA: The North River Press Publishing Corporation, 1997.
［10］ Leach L P. Critical chain project management, Third edition［M］. London: Artech House Incorporation, 2014.
［11］ Bie Li, Cui Nanfang, Zhang Xiaoming. Buffer sizing approach with dependence assumption between activities in critical chain scheduling［J］. International Journal of Production Research, 2012, 50(24): 7343-7356.
［12］ Bevilacqua M, Ciarapica F E, Giacchetta G. Critical chain and risk analysis applied to high-risk industry maintenance: a case study［J］. International Journal of Project Management, 2009, 27(4): 419-432.
［13］ Chen Zhi, Demeulemeester E, Bai Sijun, et al. A Bayesian approach to set the tolerance limits for a statistical project control method［J］. International Journal of Production Research, 2020, 58(10): 3150-3163.
［14］别黎, 崔南方. 关键链动态缓冲监控方法研究［J］. 中国管理科学, 2010, 18(6): 97-103.Bie Li, Cui Nanfang. Research on dynamic buffer monitoring in critical chain project management［J］. Chinese Journal of Management Science, 2010, 18(6): 97-103.
［15］ Zhang Junguang, Shi Ruixia, Diaz E. Dynamic monitoring and control of software project effort based on an effort buffer［J］. Journal of the Operational Research Society, 2015, 66(9): 1555-1565.
［16］张俊光, 万丹. 关键链项目实时滚动监控方法研究［J］. 中国管理科学, 2018, 26(4): 171-179.Zhang Junguang, Wan Dan. Dynamic real-time monitoring and control of a critical chain project［J］. Chinese Journal of Management Science, 2018, 26(4): 171-179.
［17］ Zhang Junguang, Jia Saike, Diaz E. Dynamic monitoring and control of a critical chain project based on phase buffer allocation［J］. Journal of the Operational Research Society, 2018, 69(12): 1966-1977.
［18］张静文, 刘耕涛. 基于鲁棒性目标的关键链项目调度优化［J］. 系统工程学报, 2015, 30(1): 135-144.Zhang Jingwen, Liu Gentao. Critical chain project scheduling problem with the robust objective［J］. Journal of Systems Engineering, 2015, 30(1): 135-144.
［19］胡雪君, 王建江, 崔南方. 基于统计过程控制的两阶段缓冲监控方法［J］. 控制与决策, 2020, 35(6): 1453-1462.Hu Xuejun, Wang Jianjiang, Cui Nanfang. Two-stage buffer monitoring method based on statistical process control［J］. Control and Decision, 2020, 35(6): 1453-1462.
［20］ Zhao Yan, Cui Nanfang, Tian Wendi. A two-stage approach for the critical chain project rescheduling［J］. Annals of Operations Research, 2020, 285(1): 67-95.
［21］ Zhang Junguang, Wan Dan. Integrated buffer monitoring and control based on grey neural network［J］. Journal of the Operational Research Society, 2019, 70(3): 516-529.
［22］ Vanhoucke M. On the dynamic use of project performance and schedule risk information during project tracking［J］. Omega, 2011, 39(4): 416-426.
［23］别黎, 崔南方, 田文迪,等. 基于活动敏感性的动态缓冲监控方法研究［J］. 中国管理科学, 2014, 22(10):113-121.Bie Li, Cui Nanfang, Tian Wendi, et al. Research on activity sensitivity index based dynamic buffer monitoring method［J］. Chinese Journal of Management Science, 2014, 22(10):113-121.
［24］ Hu Xuejun, Cui Nanfang, Demeulemeester E, et al. Incorporation of activity sensitivity measures into buffer management to manage project schedule risk［J］. European Journal of Operational Research, 2016, 249(2): 717-727.
［25］ Elmaghraby S E. On criticality and sensitivity in activity networks［J］. European Journal of Operational Research, 2000, 127(2): 220-238.
［26］ Ballesteros P, Cerezo A, Otero M, et al. Performance comparison of activity sensitivity metrics in schedule risk analysis［J］. Automation in Construction, 2019, DOI: 10.1016/S0926580519301682.
［27］ Song Jie, Martens A, Vanhoucke M. Using schedule risk analysis with resource constraints for project control［J］. European Journal of Operational Research, 2021, 288(3): 736-752.
［28］ Madadi M, Iranmanesh H. A management oriented approach to reduce a project duration and its risk (variability)［J］. European Journal of Operational Research, 2012, 219(3): 751-761.
［29］施骞, 王雅婷, 龚婷. 项目缓冲设置方法及其评价指标改进［J］. 系统工程理论与实践, 2012, 32(8): 1739-1746.Shi Qian, Wang Yating, Gong Ting. An improved approach for project buffer sizing and evaluation［J］. Systems Engineering-Theory & Practice. 2012, 32(8): 1739-1746.
［30］顾蛟. YS公司智慧党建软件开发项目进度管理研究［D］. 成都：电子科技大学，2020.Gu Jiao. Research on schedule management of intelligent party building software project of YS company［D］. Chengdu: University of Electronic Science and Technology of China, 2020.

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