交付时间敏感型需求下的定制化供应链对冲决策研究

doi:10.12005/orms.2025.0044

运筹与管理 ›› 2025, Vol. 34 ›› Issue (2): 66-72.DOI: 10.12005/orms.2025.0044

交付时间敏感型需求下的定制化供应链对冲决策研究

翟月^1,2, 郑大昭³, 徐素秀⁴, 黎建强⁵

1.北京交通大学经济管理学院,北京 100044;
2.北京交通大学中东欧研究中心,北京 100044;
3.香港理工大学工商管理学院,香港 999077;
4.北京理工大学管理学院,北京 100081;
5.陕西师范大学国际商学院,陕西西安 710062

收稿日期:2022-12-23 出版日期:2025-02-25 发布日期:2025-06-04
通讯作者: 徐素秀(1984-),男,浙江台州人,博士,教授,研究方向:物流与供应链管理,交通经济学。Email: xusuxiu@bit.edu.cn。
作者简介:翟月(1991-),女,北京人,博士,副教授,研究方向:供应链管理,合作机制设计
基金资助:
国家自然科学基金资助项目(71901023,72471028)

MTO Supply Chain Hedging Strategy under Delivery Time Sensitive Demand

ZHAI Yue^1,2, ZHENG Dazhao³, XU Suxiu⁴, LAI Kinkeung⁵

1. School of Economics and Management, Beijing Jiaotong University, Beijing 100044, China;
2. Research Center for Central and Eastern Europe, Beijing Jiaotong University, Beijing 100044, China;
3. Faculty of Business, The Hong Kong Polytechnic University, Hong Kong 999077, China;
4. School of Management, Beijing Institute of Technology, Beijing 100081, China;
5. International Business School, Shaanxi Normal University, Xi'an 710062, China

Received:2022-12-23 Online:2025-02-25 Published:2025-06-04

摘要/Abstract

摘要： 随着定制化供应链的普及,顾客对于定制化产品的交付期以及准时交付率变得日益敏感。为了在定制化市场中保持竞争优势,零售商需要在缩短交付期的同时确保按时交付的准时率,因而希望制造商通过压缩生产时间来缓解因生产环节不确定性而造成的延期惩罚。这种压缩生产时间的策略称为生产时间对冲策略。虽然该策略可以提升零售商的利润,却要求制造商进行额外成本投入。为解决零售商与制造商的决策冲突问题,本文提出基于承诺交付期及生产时间对冲补偿成本的合作机制。针对不同的市场权利结构分别建立了集中决策模型,Nash博弈模型以及零售商主导的Stackelberg博弈模型。结果表明:生产时间对冲策略有效提升了供应链整体利润并增加了市场需求,并且,通过引入生产时间对冲成本补偿,实现了零售商与制造商的共赢. 当需求对承诺交付期较敏感时,零售商的承诺交付期减少而制造商的生产时间对冲值增加,反之亦然。

关键词: 按订单生产, 交付期, 时间对冲, 协调机制

Abstract: With the rapid development of make-to-order (MTO) supply chain, customers are becoming more and more sensitive to the service level, e.g., the delivery lead-time and delivery efficiency. A short delivery stimulates the market demand and vice versa. In order to maintain competitive advantage in the customized market, the retailer needs to shorten the delivery time while ensuring the efficiency of on-time delivery. However, there exist inherent uncertainties such as machine failure, a shortage of raw materials and unskilled work crew in the production process. The MTO manufacturer often fails to satisfy the required delivery time. Unfortunately, the retailer must pay tardiness penalty if the actual delivery time exceeds the promised delivery time. In order to improve on-time delivery rate under a short delivery time, the retailer often requires the manufacturer to hedge against its production uncertainty, which is defined as production lead-time hedging in this research. Although the production lead-time hedging strategy may improve the retailer's profitability by mitigating tardiness delivery, the manufacturer must spend more on the hedging, e.g., hiring more workers, leasing more production lines, and requiring workers to work overtime. Hence, the manufacturer will withdraw from the production lead-time hedging strategy if its profit is worse off. To solve the conflict between the retailer and manufacturer, we propose a side payment contract under which the retailer makes a direct money transfer to the manufacturer for compensating its hedging effort. This work is devoted to exploring the effect of production lead-time hedging on the delivery time decision, on-time delivery probability, and profits of each party while examining the effect of the proposed side payment contract on coordinating the decentralized supply chain.
We consider three scenarios corresponding to different power settings, namely, the centralized model, the Nash game model and retailer-led Stackelberg game model. Under the centralized model, the decisions are made by a super manager who aims at maximizing the profit of entire supply chain. Under the Nash game model, the retailer decides the delivery time while the manufacturer decides the production lead-time hedging amount simultaneously. Under the retailer-led Stackelberg game model, the retailer who acts as the game leader chooses the delivery time at the first stage. Given the delivery time, the manufacturer chooses the production lead-time decision at the second stage. By analyzing the game equilibrium, we derive the optimal decision for each participant.
Through numerical analysis and model comparison, we find that the production lead-time hedging strategy improves the channel profit as well as promote the market demand. The win-win outcome is reached through the proposed side payment contract. The major findings and managerial implications are summarized as below:
First, adopting production lead-time hedging strategy facilitates the retailer to choose a shorter delivery time. Especially, under the centralized model, the delivery time reaches its shortest while the production lead-time hedging amount reaches its highest. The production lead-time hedging strategy protects both retailer's and manufacturer's profits even when the consumer's delivery time sensitivity or the tardiness penalty becomes higher. The relationship between different game models depends on the tardiness penalty sharing rate, production lead-time hedging cost and unit tardiness penalty.
Second, the retailer should actively provide side payment contract to encourage the manufacturer to take part in the production lead-time hedging strategy. Although the retailer should pay extra cost for hedging, his profit is compensated by the reduced tardiness penalty and increased sales. Under the decentralized supply chain, each party's profit under the retailer-led Stackelberg game is higher than that under the Nash game. Hence, we suggest the manufacturer should not blindly pursue an equal power structurer, for the retailer-led Stackelberg game is the dominant strategy for both parties.
Third, in the light of the equilibrium decisions, we suggest both the retailer and manufacturer should consider the tardiness penalty, retail price, consumer delivery time sensitivity, consumer price sensitivity and initial market size while optimizing their operation decisions. From the retailer's perspective, raising retail price while selling products to market with low sensitivity towards price/delivery time, or low tardiness penalty brings more profits. From the manufacturer's perspective, selling products to market with low or moderate delivery time sensitivity and retail price increases its profitability.

Key words: make-to-order (MTO), delivery lead-time, lead-time hedging, coordination mechanism

中图分类号:

F274

翟月, 郑大昭, 徐素秀, 黎建强. 交付时间敏感型需求下的定制化供应链对冲决策研究[J]. 运筹与管理, 2025, 34(2): 66-72.

ZHAI Yue, ZHENG Dazhao, XU Suxiu, LAI Kinkeung. MTO Supply Chain Hedging Strategy under Delivery Time Sensitive Demand[J]. Operations Research and Management Science, 2025, 34(2): 66-72.

参考文献

[1] 孟炯,张杨,曾波.基于个性化需求的产品竞争供应链结构选择[J].中国管理科学,2019,27(12):67-76.
[2] NIU B, DAI Z, ZHUO X. Co-opetition effect of promised-delivery-time sensitive demand on air cargo carriers' big data investment and demand signal sharing decisions[J]. Transportation Research Part E: Logistics and Transportation Review, 2019, 123: 29-44.
[3] 邵建军,柯大钢.价格、时间敏感需求下的供应链价格与交付期管理[J].管理工程学报,2008,22(4):90-94+112.
[4] DONG L, KOUVELIS P, SU P. Operational hedging strategies and competitive exposure to exchange rates[J]. International Journal of Production Economics, 2014, 153: 215-229.
[5] STING F J, HUCHZERMEIER A. Operational hedging and diversification under correlated supply and demand uncertainty[J]. Production and Operations Management, 2014, 23(7): 1212-1226.
[6] HARRISON J M, VAN MIEGHEM J A. Multi-resource investment strategies: Operational hedging under demand uncertainty[J]. European Journal of Operational Research, 1999, 113(1): 17-29.
[7] HU Y, GUAN Y, & LIU T. Lead-time hedging and coordination between manufacturing and sales departments using Nash and Stackelberg games[J]. European Journal of Operational Research, 2011, 210(2): 231-240.
[8] 马士华,王福寿.时间价格敏感型需求下的供应链决策模式研究[J].中国管理科学,2006,14(3):13-19.
[9] 董毓芬,何平,徐晓燕.时间价格敏感型需求下的二阶段供应链协调模型[J].中国管理科学,2011,19(4):93-97.
[10] 谢祥添,张毕西.基于需求交货时间敏感性交货时间与产能决策[J].系统工程理论与实践,2015,35(9):2242-2250.
[11] BHASKARAN S R, KRISHNAN V. Effort, revenue, and cost sharing mechanisms for collaborative new product development[J]. Management Science, 2009, 55(7): 1152-1169.
[12] CHEN C. Design for the environment: A quality-based model for green product development[J]. Management Science, 2001, 47(2): 250-263.
[13] ZHU S X. Integration of capacity, pricing, and lead-time decisions in a decentralized supply chain[J]. International Journal of Production Economics, 2015, 164: 14-23.
[14] 任廷海,张旭梅,周茂森,等.考虑交付质量和交付期约束的移动应用供应链决策与协调[J].系统工程理论与实践,2019,39(3):615-634.
[15] ZHAO J, ZHOU Y W, CAO Z H, et al. The shelf space and pricing strategies for a retailer-dominated supply chain with consignment based revenue sharing contracts[J]. European Journal of Operational Research, 2020, 280(3): 926-939.

交付时间敏感型需求下的定制化供应链对冲决策研究

MTO Supply Chain Hedging Strategy under Delivery Time Sensitive Demand

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 14

编辑推荐

Metrics

[1]	林新宇, 刘国山, 王敏. 基于活动切割机制的分布式多项目柔性调度优化研究[J]. 运筹与管理, 2025, 34(1): 19-26.
[2]	何勇, 郭健. 文旅IP产品供应链动态开发和协调机制研究[J]. 运筹与管理, 2024, 33(9): 49-55.
[3]	周慧妮, 张斌, 谭勇, 吴鹏. 动态需求扰动下双渠道联合减排策略及协调机制分析[J]. 运筹与管理, 2024, 33(4): 181-187.
[4]	胡娇, 李莉, 朱星圳, 杨文胜. 搭便车行为影响下全渠道广告及协调策略[J]. 运筹与管理, 2024, 33(10): 232-239.
[5]	夏西强, 路梦圆, 徐春秋. 授权制造下碳交易对制造/再制造影响及协调机制研究[J]. 运筹与管理, 2022, 31(5): 136-142.
[6]	王滔, 颜波. 基于渠道溢出效应的在线渠道协调研究[J]. 运筹与管理, 2022, 31(12): 173-178.
[7]	徐飞, 王红蕾. 交货期差异下的双渠道订货与协调优化策略[J]. 运筹与管理, 2020, 29(4): 121-129.
[8]	钱茜, 杨扬, 徐凯. 考虑零售商促销策略的供应链融资及运营策略研究[J]. 运筹与管理, 2020, 29(10): 112-119.
[9]	杜杨, 丰景春. 基于公私不同风险偏好的PPP项目政府补偿机制研究[J]. 运筹与管理, 2017, 26(11): 190-199.
[10]	吴忠和, 陈宏, 吴晓志, 解东川. 突发事件下不对称信息供应链协调机制研究[J]. 运筹与管理, 2015, 24(1): 48-56.
[11]	刘红生, 李帮义. 银行责任延伸信贷资金循环系统的运转与传导利率作用机制研究[J]. 运筹与管理, 2014, 23(5): 213-220.
[12]	夏兆敏, 孙世民. 基于微分博弈的二级猪肉供应链质量行为协调机制研究[J]. 运筹与管理, 2014, 23(2): 198-205.
[13]	王玉华, 惠晓峰, 李敦亮. 基于STR模型的人民币汇率利率协调机制研究[J]. 运筹与管理, 2014, 23(1): 179-187.
[14]	何芳, 温修春. 我国农村土地间接流转供应链的利益协调机制研究——基于委托代理模型[J]. 运筹与管理, 2013, 22(4): 60-67.