动态不确定环境下基于多层级备份策略的供应链网络性能研究

doi:10.16381/j.cnki.issn1003-207x.2023.0173

摘要/Abstract

摘要：

“双碳”目标下，构建注重环保性能的供应链网络已成为必然，而供应链网络处于动态不确定环境中，应采取一定的策略保证其性能。本文考虑随机需求和不确定中断的影响，采用多层级备份策略构建供应链网络，量化分析多层级匹配关系下的供应链网络的中断风险。考虑到供应链网络结构的动态性、非线性、不确定性，本文构建系统动力学模型，从经济、环境、可靠性等维度，分析动态不确定环境下基于多层级备份策略的供应链网络性能。研究结果表明，供应链网络运行时间越长，中断信度越大，多层级备份策略提升供应链网络性能的效果越显著。且当中断信度较大时，若不采用多层级备份策略，相较于运输中断，供应商中断会更大程度地损害供应链网络的经济性能。此外，需求稳定性降低会导致供应链网络的经济、环境、可靠性维度的性能出现不同方向的波动。这为优化供应链网络结构及供应商选择提供依据，也为供应链网络实现低碳、稳健发展提供理论支持。

关键词: 供应链网络性能, 多层级备份策略, 系统动力学模型, 不确定理论

Abstract:

Affected by the epidemic， the global supply chain network has been severely impacted by supply chain disruptions， forcing many enterprises to suspend production， resulting in serious economic losses. Notably， even in the face of uncertainties such as disruptions， supply chain sustainability is still valued. This is because it has become inevitable to build a supply chain network that focuses on environmental performance under the “carbon peaking and carbon neutrality” target. Therefore， it is necessary to adopt corresponding response strategies to scientifically design the supply chain network structure and ensure the multi-dimensional dynamic performance of the supply chain network. However， existing studies have not explored supply chain network performance along three dimensions： economic， reliability， and sustainability of the supply chain. And the supply chain network structure with multi-level matching relationship formed by multiple suppliers， manufacturers， etc. is more realistic， which has been paid less attention to. In addition， dealing with disruption risk based on probability theory requires giving the probability distribution of disruptions， and the history data of supply chain disruption are very scarce， so using uncertainty theory to address subjective uncertainty can effectively improve the scientificity and credibility of quantifying disruption risk when historical data are scarce. The supply chain network is in a dynamic uncertain environment， affected by various linear， nonlinear， quantitative and qualitative factors， and the supply chain network itself is also a complex system in which factors and links interact with each other. The system dynamic （SD） approach can address nonlinear and time-sensitive behaviors in a realistic and relatively intuitive way by capturing the causal relationships between relevant factors and their corresponding behaviors， combining quantitative and qualitative aspects. Therefore， it is of great significance to investigate the supply chain network performance based on a multi-level backup strategy in a dynamic and uncertain environment using SD approach in terms of three dimensions： economic， environment and reliability.For this purpose， uncertainty theory is used to quantify and analyze supply chain disruption risk in response to the low frequency and the difficulty of obtaining data of supply and transportation disruptions. And a multi-level backup strategy is used to cope with disruption risks， and the SD model for supply chain network performance analysis is constructed based on the formed supply chain network with multi-subject and multi-level matching relationships. The metrics for evaluating supply chain network performance are extended to three dimensions： economic， environment， and reliability， to analyze the supply chain network performance based on the multi-level backup strategy in a dynamic and uncertain environment. The results show that：（1） Although the multi-level backup strategy may lead to lower profit in the initial stage of supply chain operation， it can effectively mitigate the adverse effects of disruptions on the supply chain network in the long run. Therefore， the decision of the optimal backup level should be combined with the supply chain network operation time， integrating long-term development with short-term adjustment. （2） As the belief degree of disruption increases， the profit will decrease and the supply chain risk will increase， and the larger the belief degree of disruption， the longer the supply chain network operates， and the more significant the effect of adopting multi-level backup strategy. Therefore， the higher the possibility of disruptions in the long-term， the more important it is for decision-makers to plan for “chain preparedness” and optimize the supply chain network structure in order to adapt quickly in the event of external shocks. （3） When belief degree of disruption is large， supply disruption leads to a more significant decrease in profit compared to transportation disruption if the multi-level backup strategy is not adopted. Therefore， to achieve the stability of the supply chain， the reliability of suppliers should be focused on when selecting them， and the mutual cooperation of the supply chain should be strengthened to diversify the risks. （4） The reduced stability of demand results in fluctuations in the supply chain network performance in different directions in terms of economic， environment and reliability dimensions. Therefore， decision makers should weigh the factors they care about and shift from the previous pursuit of profit optimization to a continuous shift in balancing supply chain reliability， economic efficiency and environmental benefits to shape core competitiveness. This provides a basis for optimizing the supply chain network structure and selecting supplier， and gives theoretical support for achieving low-carbon and robust development of the supply chain network.

Key words: supply chain network performance, multi-level backup strategy, system dynamic model, uncertainty theory

中图分类号:

F224

王莺潼,计小宇,孟庆春. 动态不确定环境下基于多层级备份策略的供应链网络性能研究[J]. 中国管理科学, 2025, 33(10): 316-326.

Yingtong Wang,Xiaoyu Ji,Qingchun Meng. Research on Supply Chain Network Performance Based on Multi-level Backup Strategy in Dynamic and Uncertain Environment[J]. Chinese Journal of Management Science, 2025, 33(10): 316-326.

图/表 8

图1

表1

SD模型的相关符号定义"

符号	含义（单位）
常数
MUPC $w$	制造商 $w$ 单位生产成本(元/单位)
MUPCE $w$	制造商 $w$ 单位生产碳排放(吨/单位)
UPC $s w$	制造商 $w$ 从供应商 $s$ 处购买单位产品的成本(元/单位)
UPCE $s w$	制造商 $w$ 从供应商 $s$ 处购买单位产品的碳排放(吨/单位)
R&D	研发支出(元)
TAQ	总碳排放配额(吨)
流量
MPIR $w$	制造商 $w$ 利润增长率(元/周)
SCPR	供应链利润增长率(元/周)
SCCER	供应链碳排放增长率(吨/周)
存量
MP $w$	制造商 $w$ 利润(元)
SCTP	供应链总利润(元)
SCTCE	供应链总碳排放(吨)
辅助变量
UD $s$	供应商 $s$ 中断信度(无量纲)
UD $s w$	供应商 $s$ 到制造商 $w$ 运输中断信度(无量纲)
SD $s$	供应商 $s$ 是否中断，1表示中断，0表示正常(无量纲)
TD $s w$	供应商 $s$ 到制造商 $w$ 运输过程是否中断，1表示中断，0表示正常(无量纲)
UDW $w$	制造商 $w$ 的中断风险(单位/周)
SCUDR	供应链不确定中断风险(无量纲)
theta $s w$	供应商 $s$ 及其运输到制造商 $w$ 的中断信度(无量纲)
SP $w$	制造商 $w$ 产品零售价(元/单位)
MOQ $w$	制造商 $w$ 订购数量(单位/周)
SSQ $s$	供应商 $s$ 供应数量(单位/周)
SSQ $s w$	供应商 $s$ 对制造商 $w$ 供应数量(单位/周)
MPC $w$	制造商 $w$ 生产成本(元/周)
MPPC $w$	制造商 $w$ 购买成本(元/周)
MPCE $w$	制造商 $w$ 生产碳排放(吨/周)
MPPCE $w$	制造商 $w$ 购买碳排放(吨/周)
SBC	供应商等待成本(元/周)
MCER $w$	制造商 $w$ 碳排放增长率(吨/周)
MCIR $w$	制造商 $w$ 成本增长率(元/周)
CERM	碳减排动力(无量纲)
ECE	超额碳排放(吨)
ERI	减排投资(元)
ERIC	减排系数(无量纲)
CTR	碳交易价格(元)
IS	监管强度(无量纲)
NPD	政策文件数量(个)
LF	立法基础(无量纲)
CI	碳排放强度(吨/元)

表1

图2

图3

图4

表2

不同供应层级下供应链网络性能比较"

比效项目	短期			中期			长期
$L$	1	2	3	1	2	3	1	2	3
风险			⎫			⎫			⎫
利润	⎫				⎫				⎫
碳排放强度	⎫			⎫			⎫

表2

图5

图6

参考文献 27

[1]	国务院发展研究中心.产业链供应链韧性与稳定国际论坛在杭州举行［EB/OL］.（2022-09-23）［2023-02-01］..
	Development Research Center of the State Council. The international forum on the resilience and stability of industrial and supply chain was held in Hangzhou［EB/OL］.（2022-09-23）［2023-02-01］..
[2]	Ha C， Jun H B， Ok C. A mathematical definition and basic structures for supply chain reliability： A procurement capability perspective［J］. Computers & Industrial Engineering， 2018， 120： 334-345.
[3]	Value Chain Innovation Initiative. Sustainable procurement barometer 2021［EB/OL］.（2022-12-06）［2023-02-01］..
[4]	Li G， Li X， Liu M. Inducing supplier backup via manufacturer information sharing under supply disruption risk［J］. Computers & Industrial Engineering， 2023， 176： 108914.
[5]	Wilson M C. The impact of transportation disruptions on supply chain performance［J］. Transportation Research Part E： Logistics and Transportation Review， 2007， 43（4）： 295-320.
[6]	Kara M E， Ghadge A， Bititci U S. Modelling the impact of climate change risk on supply chain performance［J］. International Journal of Production Research， 2021， 59（24）： 7317-7335.
[7]	Ghadge A， Er M， Ivanov D， et al. Visualisation of ripple effect in supply chains under long-term， simultaneous disruptions： A system dynamics approach［J］. International Journal of Production Research， 2022， 60（20）： 6173-6186.
[8]	张以彬，龙静，陈瑜. 市场需求可变的供应链中断应急策略与运作仿真［J］. 系统管理学报， 2019， 28（6）： 1202-1210.
	Zhang Y B， Long J， Chen Y. Contingency police and operation simulation of supply chain disruption with changing demand［J］. Journal of Systems & Management， 2019， 28（6）： 1202-1210.
[9]	王宇奇，曲云玉. 环境扰动下进口原油供应链网络柔性的系统动力学仿真［J］. 系统管理学报， 2019， 28（5）： 983-990.
	Wang Y Q， Qu Y Y. SD simulation of flexibility of imported crude oil supply chain network under environmental disruption［J］. Journal of Systems & Management， 2019， 28（5）： 983-990.
[10]	Shao L， Jin S. Resilience assessment of the lithium supply chain in China under impact of new energy vehicles and supply interruption［J］. Journal of Cleaner Production， 2020， 252： 119624.
[11]	Falagara Sigala I， Sirenko M， Comes T， et al. Mitigating personal protective equipment （PPE） supply chain disruptions in pandemics-a system dynamics approach［J］. International Journal of Operations & Production Management， 2022， 42（13）： 128-154.
[12]	Rathore R， Thakkar J J， Jha J K. Impact of risks in foodgrains transportation system： A system dynamics approach［J］. International Journal of Production Research， 2021， 59（6）： 1814-1833.
[13]	Li H， Pedrielli G， Lee L H， et al. Enhancement of supply chain resilience through inter-echelon information sharing［J］. Flexible Services and Manufacturing Journal， 2017， 29（2）： 260-285.
[14]	Olivares-Aguila J， Elmaraghy W. System dynamics modelling for supply chain disruptions［J］. International Journal of Production Research， 2021， 59（6）： 1757-1775.
[15]	赖新峰，王鑫，陈志祥. 多式联运模式下跨国供应链运输中断风险系统动力学仿真与分析——以快消食品供应链为例［J］.系统管理学报，2022，31（5）： 825-839.
	Lai X F， Wang X， Chen Z X. System dynamic-based risk analysis of transportation disruption in transnational supply chain in different multimodal transportation modes： A case study of FMCG food supply chain［J］. Journal of Systems & Management， 2022， 31（5）： 825-839.
[16]	廖诺，赵亚莉，贺勇，等. 碳交易政策对电煤供应链利润及碳排放量影响的仿真分析［J］. 中国管理科学， 2018， 26（8）： 154-163.
	Liao N， Zhao Y L， He Y， et al. Effects of carbon trading policies on profit and carbon emission of electric-coal supply chain based on simulation analysis［J］. Chinese Journal of Management Science， 2018， 26（8）： 154-163.
[17]	Cao Y， Zhao Y， Wen L， et al. System dynamics simulation for CO₂ emission mitigation in green electric-coal supply chain［J］. Journal of Cleaner Production， 2019， 232： 759-773.
[18]	Naderi K， Ahari R M， Jouzdani J， et al. System dynamics model of production-inventory-routing system in the green supply chain［J］. Journal of Intelligent & Fuzzy Systems， 2021， 40（6）： 11441-11454.
[19]	邵必林，胡灵琳. 绿色供应链参与行为演化博弈分析——基于系统动力学视角［J］. 科研管理， 2021， 42（11）： 171-181.
	Shao B L， Hu L L. A game analysis of the evolution of participation behavior of green supply chain： A study based on the system dynamics perspective［J］. Science Research Management， 2021， 42（11）： 171-181.
[20]	贺勇，卫岂伦，廖诺. 基于系统动力学的电煤供应链节能减排路径仿真分析［J］. 工业工程， 2022， 25（3）： 39-46+94.
	He Y， Wei Q L， Liao N. Path simulation and analysis of energy saving and emission reduction in electric-coal supply chain based on system dynamics［J］. Industrial Engineering Journal， 2022， 25（3）： 39-46+94.
[21]	Wang X， Du Q， Lu C， et al. Exploration in carbon emission reduction effect of low-carbon practices in prefabricated building supply chain［J］. Journal of Cleaner Production， 2022， 368： 133153.
[22]	Liu B. Uncertainty Theory： A branch of mathematics for modeling human uncertainty［M］. Berlin： Springer， 2010.
[23]	Yan S， Ji X. Supply chain network design under the risk of uncertain disruptions［J］. International Journal of Production Research， 2020， 58（6）： 1724-1740.
[24]	Huang X， Song L. An emergency logistics distribution routing model for unexpected events［J］. Annals of Operations Research， 2018， 269（1）： 223-239.
[25]	巩在武，阳佳琦. 考虑灾民心理的多周期应急物资调度不确定规划建模研究［J］. 中国管理科学， 2025， 33（3）： 209-222.
	Gong Z W， Yang J Q. Study on uncertain programming modeling of multi-period emergency material allocation considering the psychology of victims［J］. Chinese Journal of Management Science，2025，33（3）： 209-222.
[26]	Qin Z. Mean-variance model for portfolio optimization problem in the simultaneous presence of random and uncertain returns［J］. European Journal of Operational Research， 2015， 245（2）： 480-488.
[27]	马浚洋，黄晓霞，傅颖诗，等. 复杂不确定环境下考虑代理人通过努力减少项目持续期限的最优代理合同［J］. 中国管理科学， 2021， 29（5）： 138-146.
	Ma J Y， Huang X X， Fu Y S， et al. Optimal contract for the agency problem considering agent’s uncertain effort in reducing project duration［J］. Chinese Journal of Management Science， 2021， 29（5）： 138-146.