复杂产品项目工作分解绩效预测的系统动力学模型

任南, 何彦昕, 马梦园, 吴君民

系统工程理论与实践 ›› 2014, Vol. 34 ›› Issue (12) : 3113-3120.

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系统工程理论与实践 ›› 2014, Vol. 34 ›› Issue (12) : 3113-3120. DOI: 10.12011/1000-6788(2014)12-3113
论文

复杂产品项目工作分解绩效预测的系统动力学模型

    任南, 何彦昕, 马梦园, 吴君民
作者信息 +

Performance prediction of work breakdown structure for complex product project based on system dynamics

    REN Nan, HE Yan-xin, MA Meng-yuan, WU Jun-min
Author information +
文章历史 +

摘要

基于复杂产品项目工作分解的特征和系统动力学在解决系统本质行为和机理方面的优势, 建立系统动力学模型, 用以分析对产品复杂度的把握、核心技术的创新能力、人员动因、 合作伙伴和外部环境对工作分解绩效的发展影响, 并对特大型船舶制造项目进行动态仿真, 分析和预测工作分解的绩效和可能存在的问题, 结果表明: 对产品复杂度的把握和核心技术的创新能力是工作分解绩主要压力, 因此导致的企业投入分配比例问题将是工作分解高效进行的主要制约因素, 主要影响因素相互协调配合才能有效提升工作分解绩效.

Abstract

In virtue of the character of work breakdown structure (WBS) for complex product project and strongpoint of system dynamic in resolve essential conduct and mechanism of system, the research used the method of system dynamic to construct the dynamic model through system analysis, and analyzed the effect of product complexity, core technology innovation ability, staff motivation, partners, external environment on performance of WBS based on the model, the development trends of super major shipbuilding project were simulated and performance of WBS and problems were analyzed and forecasted. The results show that product complexity and innovation capabilities of core enterprise are the main pressure of performance of WBS. As a result, the reasonable redistribution of enterprise investment is the major constraint of efficiency of performance of WBS, and performance will be strengthened through the coordination of the main factors.

关键词

复杂产品项目 / 工作分解结构(WBS) / 绩效预测 / 影响因素 / 系统动力学

Key words

complex product project / work breakdown structure (WBS) / performance prediction / influence factors / system dynamics

引用本文

导出引用
任南 , 何彦昕 , 马梦园 , 吴君民. 复杂产品项目工作分解绩效预测的系统动力学模型. 系统工程理论与实践, 2014, 34(12): 3113-3120 https://doi.org/10.12011/1000-6788(2014)12-3113
REN Nan , HE Yan-xin , MA Meng-yuan , WU Jun-min. Performance prediction of work breakdown structure for complex product project based on system dynamics. Systems Engineering - Theory & Practice, 2014, 34(12): 3113-3120 https://doi.org/10.12011/1000-6788(2014)12-3113
中图分类号: F270.5   

参考文献

[1] Agarwal A, Colak S, Erenguc S. A neurogenetic approach for the resource-constrained project scheduling problem[J]. Computer and Operations Research, 2011, 38(1): 33-50.
[2] Boysen N F M.A versatile algorithm for assembly line balancing[J].European Journal of Operational Research, 2008, 184(1): 39-56.
[3] Park C, Lee S, Son J, et al. Integrated cost and schedule control in the Korean construction industry based on a modified work-packaging model[J]. NRC Research Press Web, 2008, 13(35): 225-235.
[4] 胡杨博,莫蓉,常智勇,等. 基于工作分解结构复杂多级项目的进度监控技术研究[J]. 现代制造工程, 2008(2): 17-19.Hu Yangbo, Mo Rong, Chang Zhiyong, et al. Research on schedule monitoring technology for the complex multilevel project based on WBS[J]. Modern Manufacturing Engineering, 2008(2): 17-19.
[5] Golpayegani S A H, Emamizadeh B. Designing work breakdown structures using modular neural networks[J]. Decision Support Systems, 2007, 44(1): 202-222.
[6] Bai Y, Zhao Y, Chen Y, et al. Designing domain work breakdown structure (DWBS) using neural networks[J]. Advances in Neural Networks, 2009: 1146-1153.
[7] Lee J, Deng W Y, Lee W T, et al. Integrating process and work breakdown structure with design structure matrix[J]. Journal of Advanced Computational Intelligence and Intelligent Informatics, 2010, 14(5): 512-522.
[8] 梁学栋,刘柱胜,杨育,等. 基于依赖关系的带权协同任务排序[J].系统工程, 2011, 29(3): 98-102.Liang Xuedong, Liu Zhusheng, Yang Yu, et al. Weighting collaborative task sequencing based on dependengcy logic breakdown[J]. Systems Engineering, 2011, 29(3): 98-102.
[9] 谢磊,陈群,虞华. 城市轨道交通建设管理中WBS矩阵技术研究[J].中国工程科学, 2010(1): 102-107.Xie Lei, Chen Qun, Yu Hua. Study on WBS matrix for construction management in urban rail-transit[J]. Engineering Science, 2010(1): 102-107.
[10] Vanhoucke M. On the dynamic use of project performance and schedule risk information during project tracking[J]. Omega, 2011, 39(4): 416-426.
[11] 白勇军,陈阳,赵勇. 基于WBS的虚拟采办系统分析与协同建模研究[J].系统仿真学报, 2011(12): 2768-2776.Bai Yongjun, Chen Yang, Zhao Yong. System analysis and collaborative modeling research on WBS-based SBA[J]. Journal of System Simulation, 2011(12): 2768-2776.
[12] 崔淼, 苏敬勤, 王淑娟. 后发复杂产品系统制造企业的技术演化——一个探索性案例研究[J]. 南开管理评论, 2012, 15(2): 128-135.Cui Miao, Su Jingqin, Wang Shujuan. Complex product system latecomer manufacturers' technology evolution: An exploratory case study[J]. Nankai Business Review, 2012, 15(2): 128-135.
[13] Zheng X L, Lin Y, Ji Z S. Collaborative multidisciplinary decision making based on game theory in ship preliminary design[J]. Journal of Marine Science and Technology, 2009, 14(3): 334-344.
[14] Nakamura H, Kajikawa Y, Suzuki S. Multi-level perspectives with technology readiness measures for aviation[J]. Sustainability Science, 2013, 8(1): 87-101.
[15] 周宇,谭跃进,姜江,等.面向能力需求的武器装备体系组合规划模型与算法[J]. 系统工程理论与实践, 2013, 33(3): 810-816.Zhou Yu, Tan Yuejin, Jiang Jiang, et al. Capability requirements oriented weapon system of systems portfolio planning model and algorithm[J]. Systems Engineering - Theory & Practice, 2013, 33(3): 810-816.
[16] Goyal S, Grover S. Manufacturing system's effectiveness measurement by using combined approach of ANP and GTMA[J]. International Journal of System Assurance Engineering and Management, 2012(10): 18-30.
[17] 曾鹏,魏法杰,乐群星. 基于WBS+BP的武器系统研制成本控制体系研究[J]. 中国管理科学, 2005, 13(10): 288-292.Zeng Peng, Wei Fajie, Yue Qunxing. A new weapon R&D cost controlling system based on WBS+BP[J]. Chinese Journal of Management Science, 2005, 13(10): 288-292.
[18] Prencipe A. Breadth and depth of technological capabilities in CoPS: The ease of the aircraft engine control system[J]. Research Policy, 2000, 29(7): 895-911.
[19] 于逢平, 崔岫.船舶企业海洋工程项目计划管理模式[J]. 中国造船, 2008, 49(3): 136-145.Yu Fengping, Cui Xiu. Scheduling management model of offshore project in a shipyard[J]. Shipbuilding of China, 2008, 49(3): 136-145.
[20] 李天恩, 何桢. 复杂产品多故障诊断中的核模糊聚类方法[J]. 系统工程理论与实践, 2013, 33(1): 181-186.Li Tianen, He Zhen. Kernel-based fuzzy clustering algorithm for multi-faults diagnosis of complex products[J]. Systems Engineering - Theory & Practice, 2013, 33(1): 181-186.
[21] 吴传荣, 陈英武. 高技术企业技术创新网络中知识转移时间优化研究[J]. 系统工程理论与实践, 2013, 33(4): 955-962. Wu Chuanrong, Chen Yingwu. Time optimization of knowledge transfer in high-tech enterprises innovation networks[J]. Systems Engineering - Theory & Practice, 2013, 33(4): 955-962.
[22] 方来坛, 时勘, 张风华, 等. 员工敬业度、工作绩效与工作满意度的关系研究[J]. 管理评论, 2011, 12(23): 108-115.Fang Laitan, Shi Kan, Zhang Fenghua, et al. Relationship research among employee engagement, work performance and work satisfaction[J]. Management Review, 2011, 12(23): 108-115.
[23] Pieterse A N, Van Knippenberg D, Schippers M, et al. Transformational and transactional leadership and innovative behavior: The moderating role of psychological empowerment[J]. Journal of Organizational Behavior, 2010, 31(4): 609-623.
[24] 李存斌, 陆龚曙.工程项目风险元传递的系统动力学模型[J]. 系统工程理论与实践, 2012, 32(12): 2731-2739.Li Cunbin, Lu Gongshu. System dynamics model of construction project risk element transmission[J]. Systems Engineering - Theory & Practice, 2012, 32(12): 2731-2739.
[25] 张燕君, 黄健柏.基于人格的人与职务动态匹配及其对绩效影响作用的实证研究[J]. 系统工程, 2011, 29(3): 86-92.Zhang Yanjun, Huang Jianbo. An empirical study on impact of dynamic person-job fit based on personality to performance[J]. Systems Engineering, 2011, 29(3): 86-92.
[26] Claudia S. Complementarities of innovation activities: An empirical analysis of the German manufacturing sector[J]. Research Policy, 2008, 37(9): 1492-1503.
[27] Motohashi K, Yun X. China's innovation system reform and growing industry and science linkages[J]. Research Policy, 2007, 36(8): 1251-1260.
[28] Jirjah U, Kraft K. Do spillovers stimulate incremental or drastic product innovations? Hypotheses and evidences of scope from German establishment data[J]. Oxford Bulletin of Economics and Statistics, 2011, 73(4): 509-538.
[29] 刘炜, 马文聪, 樊霞. 产学研合作与企业内部研发的互动关系研究——基于企业技术能力演化的视角[J]. 科学学研究, 2012, 30(12): 1853-1861.Liu Wei, Ma Wencong, Fan Xia. Research on the interaction between university-industry collaboration and internal R&D - A perspective form the technological capability evolution[J]. Studies in Science of Science, 2012, 30(12): 1853-1861.
[30] 马文聪, 朱桂龙.环境动态性对技术创新和绩效关系的调节作用[J]. 科学学研究, 2011, 29(3): 454-460.Ma Wencong, Zhu Guilong. Environmental dynamism as a moderator between the relationship of technical innovation and performance[J]. Studies in Science of Science, 2011, 29(3): 454-460.

基金

国家自然科学基金(71171101,71271104);国家自然科学基金重点项目(71331003);教育部人文社科基金(11YJA630151);江苏省"青蓝工程"
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