考虑线上—线下协同的项目调度与人员指派集成优化研究

doi:10.16381/j.cnki.issn1003-207x.2023.0374

Abstract

Abstract:

With the rapid development of information technology and the leading wave of digital transformation， many enterprises begin to transform operations such as online-onsite collaborative operation mode， based on the digital technologies of cloud computing， artificial intelligence， and digital platforms. In the context of digitalization， online-onsite collaborative operation mode will be widely applied with the integration of platforms and tools， and the creation of intelligent gadgets， in order to realize lowering costs and boosting productivity. For example， some tasks in projects including installation， inspection， testing， etc.， are more suitable for online-onsite collaborative mode， that is， technological experts execute guidance online by visualization through information equipment.Here， an extension of multi-skill resource-constrained project scheduling problem （MSRCPSP） is proposed and investigated in this study. The distinct feature of collaboration between online employees and onsite employees is considered in MSRCPSP. More specifically， the human resources are categorized into online workforce who can only perform knowledge-based skills and onsite workforce with both knowledge-based skills and operation-based skills. The project activity network is consisted of two types of activities： 1） purely online activities which can only be executed by online workforce； 2） onsite activities which can be done in two ways， one is executed by onsite workforce alone， the other is executed by collaboration of online and onsite workforce. Compare with the traditional MSRCPSP， there are new decision variables in this problem for reasonably selecting execution mode for each onsite activities， the purely onsite mode， or the online-onsite collaboration mode. For the purely onsite mode， the onsite workforce who meet the conditions is scarce so there exists a delay on the spatial transfer and it is hard to implement parallel multitasking operations. For the online-onsite collaboration mode， although the resource waiting time is alleviated， the operational efficiency is highly relied on the collaboration between online workforce and onsite workforce especially for the challenging activities， which will cause the extension of processing time. Consequently， with the goal of minimizing the project completing time， a programming model is proposed to gain the optimal activity execution modes， scheduling scheme and workforce assignment under the constraints of resource limitation， skill type and level requirements， precedence relations. An adapted genetic algorithm embedded nine strategies is designed based on "highest level of skill first"， "the most average workload first" and "the shortest processing time first"， to satisfy the computational requirements of large-scale problems.The instances for different problem scales， namely 10， 20， 30， 60， 90， 120， are randomly generated. The large number of experiments are conducted， the model is validated and the proposed genetic algorithm has proven to be effective compared with Gurobi. Besides， the results are analyzed and several managerial insights are drawn. First， an increase in the proportion of online activities contributes to the shortening of the processing time， while an attention should also be paid to the overloaded online activities. Second， whether to adopt a collaborative mode should be fully deliberated including the durational amplifying effect of the collaboration difficulty， the scarcity of online and onsite resources， and the disparity in the knowledge-based level between online and onsite resources. Third， the frequencies of transfer are influenced by the ratio of onsite resources， so onsite resources should be added appropriately to reduce the flow frequency between regions when the transfer time is lengthy.This research can effectively offer guidance on the assignment of online and onsite workforce for projects with the rapid development and application of various digital technologies in many enterprises. Besides， it extends the research paradigm and theoretical underpinnings of the MSRCPSP.

Key words: project scheduling, personnel assignment, online-onsite collaboration, multi-skilled employees, genetic algorithm

CLC Number:

C935

Sha Tao, Jing Jin, Jing Zhou. The Integrated Optimization Project Scheduling and Personnel Assignment Considering Online-Onsite Collaboration[J]. Chinese Journal of Management Science, 2025, 33(6): 85-95.

Figures/Tables 10

References 21

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活动集合	作业方式	策略编号	优先规则
活动集合	作业方式	策略编号	技能水平高优先	工作量均衡优先	到达时间早优先
N1	仅线上作业	P1	策略1	策略2	策略3
N1	仅线上作业	P1	线上资源知识技能水平高者优先	线上资源累积工作次数少者优先	线上资源到达时间早者优先
N2	仅线下作业	P2	策略4	策略5	策略6
	仅线下作业	P2	线下资源知识与操作技能综合水平高者优先	线下资源累积工作次数少者优先	线下资源到达时间早者优先
	线上线下协作	P3	策略7	策略8	策略9
	线上线下协作	P3	线上资源知识技能水平及线下资源操作技能水平高者优先	线上资源和线下资源累积工作次数少者优先	线上资源及线下资源到达时间早者优先

案例组	平均总工期（单位：天）		平均运行时间（单位：秒）		GAP
案例组	Gurobi	GA	Gurobi	GA	GAP
J10_1	22	22	36.48	30.02	0
J10_2	24.7	26.7	30.39	29.32	0.08
J10_3	16	19	26.09	26.71	0.19
J10_4	16.3	17	31.03	27.54	0.04
J10_5	13	13	19.69	26.13	0
J20_1	18	19.7	130.77	68.62	0.09
J20_2	28	29	111.52	56.68	0.04
J20_3	22	24	126.98	56.93	0.09
J20_4	24	25	108.25	52.99	0.04
J20_5	21	23	133.78	56.47	0.10
J301_1	53	57	4608.39	170.51	0.08
J301_2	42	43	539.20	105.67	0.02
J301_3	43	43	468.25	107.96	0
J301_4	55	61	1158.51	118.80	0.11
J301_5	31	31	451.56	108.21	0

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The Integrated Optimization Project Scheduling and Personnel Assignment Considering Online-Onsite Collaboration

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