多重不确定因素影响下的高端装备研制任务流程优化
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摘要
基于设计结构矩阵对高端装备研制任务进行仿真建模,采用蒙特卡罗方法模拟研制任务执行过程,用以估算其工期、成本、失败率等参数.将研制任务仿真嵌入到多目标优化算法中,对每个个体对应的研制任务流程进行多次仿真,以仿真输出的平均工期、成本、失败率等作为适应度评价指标,基于NSGA-III构造多目标优化算法,求解其Pareto最优解集.对每个Pareto最优解对应的研制任务流程进行更多次的仿真,在此基础上对各个研制任务流程进行深入分析、评价.最后,以某无人机研制任务为例进行应用研究,并把本文的优化结果与文献中的数据进行比较,检验了本文方法的有效性和优越性.
The simulation model of high-end equipment development task is established based on design structure matrix, and Monte Carlo method is used to simulate the execution process of the development task. The simulation outputs are used to estimate the duration, cost, failure rate and other parameters of the development task. The development task simulation is embedded into multi-objective optimization algorithm, and each individual corresponding development task process is simulated many times. The average duration, cost and failure rate of simulation outputs are used as fitness evaluation indexes. Multi-objective optimization algorithm is constructed based on non-dominated sorting genetic algorithm-III(NSGA-III),the Pareto optimal solution set is obtained by running optimization algorithm. More simulations for the development task process of each Pareto optimal solution are carried out, and the development task processes are deeply analyzed and evaluated. Finally, an uninhabited combat aerial vehicle development task is taken as an example to study the application, and the optimization result of this paper are compared with the data in the literature. The effectiveness and superiority of the proposed method are verified.
The simulation model of high-end equipment development task is established based on design structure matrix, and Monte Carlo method is used to simulate the execution process of the development task. The simulation outputs are used to estimate the duration, cost, failure rate and other parameters of the development task. The development task simulation is embedded into multi-objective optimization algorithm, and each individual corresponding development task process is simulated many times. The average duration, cost and failure rate of simulation outputs are used as fitness evaluation indexes. Multi-objective optimization algorithm is constructed based on non-dominated sorting genetic algorithm-III(NSGA-III),the Pareto optimal solution set is obtained by running optimization algorithm. More simulations for the development task process of each Pareto optimal solution are carried out, and the development task processes are deeply analyzed and evaluated. Finally, an uninhabited combat aerial vehicle development task is taken as an example to study the application, and the optimization result of this paper are compared with the data in the literature. The effectiveness and superiority of the proposed method are verified.
引文
[1] Browning T R, Eppinger S D. Modeling impacts of process architecture on cost and schedule risk in productdevelopment[J]. IEEE Transactions on Engineering Management, 2002, 49(4):428-442.
[2] Cho S H, Eppinger S D. A simulation-based process model for managing complex design projects[J]. IEEE Transactions on Engineering Management, 2005, 52(3):316-328.
[3]陈冬宇,邱莞华,杨青,等.基于DSM的复杂产品开发流程优化遗传算法[J].控制与决策,2008, 23(8):910-914.Chen D Y, Qiu W H, Yang Q, et al. DSM-based complex product development process optimization using genetic algorithm[J]. Control Decision, 2008, 23(8):910-914.
[4]杨青,吕杰峰.基于DSM返工风险评价矩阵的项目优化与仿真[J].系统工程理论与实践,2010, 30(9):1665-1671-Yang Q, Lii J F. Project optimization and simulation based on DSM rework risk evaluation matrix[J]. Systems Engineering—Theory&Practice, 2010, 30(9):1665-1671.
[5] Collins S T, Yassine A A, Borgatti S P. Evaluating product development systems using network analysis[J].Systems Engineering, 2009, 12(1):55-68.
[6] Rebentisch E, Schuh G, Riesener M, et al. Assessment of changes in technical systems and their effects on cost and duration based on structural complexity[J]. Procedia CIRP, 2016, 55:35-40.
[7] Ahmad N, Wynn D C, Clarkson J P. Estimating the process cost of implementing engineering change alternar tives[C]//Nordic Conference on Product Lifecycle Management, NordPLM, 2009:1-14.
[8]武照云,刘晓霞,李丽,等.产品开发任务分配问题的多目标优化求解[J].控制与决策,2012, 27(4):598-602.Wu Z Y, Liu X X, Li L, et al. Multi-objective optimization for task assignment problem of product development[J].Control&Decision, 2012, 27(4):598-602.
[9] Dridi O, Krichen S, Guitouni A. A multiobjective hybrid ant colony optimization approach applied to the assignment and scheduling problem[J]. International Transactions in Operational Research, 2014, 21(6):935-953.
[10] Cheng H, Chu X. Task assignment with multiskilled employees and multiple modes for product development projects[J]. International Journal of Advanced Manufacturing Technology, 2012, 61(1):391-403.
[11]李洪波,徐哲,于静.基于DSM的研发项目流程多目标仿真优化[J].系统工程理论与实践,2015, 35(1):142-149.Li H B, Xu Z, Yu J. Multi-objective simulation optimization for the process of R&D projects based on DSM[J].Systems Engineering—Theory&Practice, 2015, 35(1):142-149.
[12] Deb K, Jain H. An evolutionary many-objective optimization algorithm using reference-point based non-dominated sorting approach, part I:Solving problems with box constraints[J]. IEEE Transactions on Evolutionary Computation, 2014, 18(4):577-601.
[13] Jain H, Deb K. An evolutionary many-objective optimization algorithm using reference-point based non-dominated sorting approach, part II:Handling constraints and extending to an adaptive approach[J]. IEEE Transactions on Evolutionary Computation, 2014, 18(4):602-622.
[2] Cho S H, Eppinger S D. A simulation-based process model for managing complex design projects[J]. IEEE Transactions on Engineering Management, 2005, 52(3):316-328.
[3]陈冬宇,邱莞华,杨青,等.基于DSM的复杂产品开发流程优化遗传算法[J].控制与决策,2008, 23(8):910-914.Chen D Y, Qiu W H, Yang Q, et al. DSM-based complex product development process optimization using genetic algorithm[J]. Control Decision, 2008, 23(8):910-914.
[4]杨青,吕杰峰.基于DSM返工风险评价矩阵的项目优化与仿真[J].系统工程理论与实践,2010, 30(9):1665-1671-Yang Q, Lii J F. Project optimization and simulation based on DSM rework risk evaluation matrix[J]. Systems Engineering—Theory&Practice, 2010, 30(9):1665-1671.
[5] Collins S T, Yassine A A, Borgatti S P. Evaluating product development systems using network analysis[J].Systems Engineering, 2009, 12(1):55-68.
[6] Rebentisch E, Schuh G, Riesener M, et al. Assessment of changes in technical systems and their effects on cost and duration based on structural complexity[J]. Procedia CIRP, 2016, 55:35-40.
[7] Ahmad N, Wynn D C, Clarkson J P. Estimating the process cost of implementing engineering change alternar tives[C]//Nordic Conference on Product Lifecycle Management, NordPLM, 2009:1-14.
[8]武照云,刘晓霞,李丽,等.产品开发任务分配问题的多目标优化求解[J].控制与决策,2012, 27(4):598-602.Wu Z Y, Liu X X, Li L, et al. Multi-objective optimization for task assignment problem of product development[J].Control&Decision, 2012, 27(4):598-602.
[9] Dridi O, Krichen S, Guitouni A. A multiobjective hybrid ant colony optimization approach applied to the assignment and scheduling problem[J]. International Transactions in Operational Research, 2014, 21(6):935-953.
[10] Cheng H, Chu X. Task assignment with multiskilled employees and multiple modes for product development projects[J]. International Journal of Advanced Manufacturing Technology, 2012, 61(1):391-403.
[11]李洪波,徐哲,于静.基于DSM的研发项目流程多目标仿真优化[J].系统工程理论与实践,2015, 35(1):142-149.Li H B, Xu Z, Yu J. Multi-objective simulation optimization for the process of R&D projects based on DSM[J].Systems Engineering—Theory&Practice, 2015, 35(1):142-149.
[12] Deb K, Jain H. An evolutionary many-objective optimization algorithm using reference-point based non-dominated sorting approach, part I:Solving problems with box constraints[J]. IEEE Transactions on Evolutionary Computation, 2014, 18(4):577-601.
[13] Jain H, Deb K. An evolutionary many-objective optimization algorithm using reference-point based non-dominated sorting approach, part II:Handling constraints and extending to an adaptive approach[J]. IEEE Transactions on Evolutionary Computation, 2014, 18(4):602-622.
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