随机需求下高铁快运定价与货流分配协同优化

doi:10.16097/j.cnki.1009-6744.2026.01.018

交通运输系统工程与信息 ›› 2026, Vol. 26 ›› Issue (1): 194-204.DOI: 10.16097/j.cnki.1009-6744.2026.01.018

随机需求下高铁快运定价与货流分配协同优化

严梦荣，徐光明^*

中南大学，交通运输工程学院，长沙410075

收稿日期:2025-10-27 修回日期:2025-12-18 接受日期:2025-12-29 出版日期:2026-02-25 发布日期:2026-02-15
作者简介:严梦荣（1998—），女，江西贵溪人，博士生。
基金资助:
国家自然科学基金(72171236)；湖南省自然科学基金(2025JJ50435)。

Integrated Optimization of Pricing and Freight Flow Allocation for High-speed Railway Express Delivery with Stochastic Demand

YAN Mengrong, XU Guangming^*

School of Traffic and Transportation Engineering, Central South University, Changsha 410075, China

Received:2025-10-27 Revised:2025-12-18 Accepted:2025-12-29 Online:2026-02-25 Published:2026-02-15
Supported by:
National Natural Science Foundation of China (72171236)；Natural Science Foundation of Hunan Province, China (2025JJ50435)。

摘要/Abstract

摘要： 利用高铁客运非高峰期的运能开展高铁快运已成为铁路快捷货运发展新趋势。然而，高铁快运的定价与货流分配相互耦合，共同影响高铁快运系统的运营效率和经济效益。针对运价与需求的弹性关系以及需求不确定性带来的挑战，本文研究高铁快运定价与货流分配协同优化问题，构建考虑弹性需求、随机需求、运价上下界、列车运能和车站装卸能力等约束的两阶段随机非凸非线性规划模型，以最大化高铁快运系统期望净利润。采用外部分段近似线性化和双线性化等技术，将该模型转化为凸二次约束规划模型，并提出结合原始搜索策略的Benders分解算法进行求解。算例结果表明：与确定性模型相比，所提模型在降低运输成本的同时实现更高利润与收益，且各项指标的标准差更低，鲁棒性更强。与求解器的对比实验表明，所提算法在求解效率和质量上具有优越性能：在中小规模的5组算例中，所提算法与求解器的目标函数值之间的相对差值均在1×10^-4以内；在大规模算例中，所提算法在683.6s内获得结果，而求解器无法在规定时间内完成求解。在郑西高铁线路的应用中，所提方法实现期望净利润1465.35万元，验证了所提方法通过吸引更多快递需求，并合理分配快递到运能有限的列车上，实现需求与运输资源的有效匹配，从而显著提高了系统的运营利润。

关键词: 铁路运输, 快递定价, Benders分解算法, 高铁快运, 货流分配, 随机需求

Abstract: To fully utilize the capacity of high-speed railway during off-peak periods, high-speed railway express delivery (HSReD) emerged as a new trend in the development of railway express delivery. However, pricing and freight flow allocation problems are intertwined to determine the operational efficiency and profitability of the HSReD system. To address the challenges posed by the elastic relationship between freight price and demand, as well as stochastic demand, this paper studies the integrated optimization of pricing and freight flow allocation for HSReD by using passenger trains. A two-stage stochastic nonconvex nonlinear programming model is constructed to maximize the expected net profit of the HSReD system, considering the elastic and stochastic demand, pricing constraints, train capacity and station loading and unloading capacities. This model is reformulated into a convex quadratic constrained programming model using outer piecewise approximate linearization and bilinear linearization techniques. A benders decomposition algorithm combined with primal search strategy is developed for efficient solution. Numerical results show that: 1) Compared with the deterministic model, the proposed model achieves higher profits and revenues while reducing transportation costs, and has lower standard deviations for all indicators, demonstrating stronger robustness. 2) The comparative experiments with the solver show that the proposed algorithm has a superior performance in terms of solution efficiency and quality: in the five groups of medium and small-scale cases, the relative gap values between the objective value obtained by the proposed algorithm and the solver are all within 1×10-4 ; in the large-scale case, the proposed algorithm obtained the result within 683.6 seconds, while the solver failed to complete the solution within the specified time. 3) In the application verification on the Zhengzhou-Xi'an high-speed railway line, the proposed method achieves an expected net profit of 14.653 5 million yuan. This verified that the proposed method can attract more express delivery demands and reasonably allocate the expresses to the trains with limited transportation capacity. It achieves efficient matching between demand and capacity resources, thereby significantly increasing the operational profit of the system.

Key words: railway transportation, express delivery pricing, Benders decomposition algorithm, high-speed railway express delivery, freight flow allocation, stochastic demand

中图分类号:

U293

严梦荣, 徐光明. 随机需求下高铁快运定价与货流分配协同优化[J]. 交通运输系统工程与信息, 2026, 26(1): 194-204.

YAN Mengrong, XU Guangming. Integrated Optimization of Pricing and Freight Flow Allocation for High-speed Railway Express Delivery with Stochastic Demand[J]. Journal of Transportation Systems Engineering and Information Technology, 2026, 26(1): 194-204.

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http://www.tseit.org.cn/CN/Y2026/V26/I1/194

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随机需求下高铁快运定价与货流分配协同优化

Integrated Optimization of Pricing and Freight Flow Allocation for High-speed Railway Express Delivery with Stochastic Demand

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