多受灾点应急物资动态多阶段分配模型研究

doi:10.16381/j.cnki.issn1003-207x.2019.10.014

摘要/Abstract

摘要： 针对传统的单阶段物资分配模型可能导致应急物资分配的局部冗余或短缺、高成本、系统无法达到全局最优等现实情况，通过在指数效用函数中引入灾民物资需求的比例短缺测度公平，以物资短缺的延迟损失最小化与物资分配的总成本最小化为目标构建考虑多集散点、多配送中心和多受灾点的三级配送网络的应急物资动态多阶段分配模型，设计了目标转化与线性近似相结合的模型求解方法，并通过算例对所提出模型的有效性和可行性进行了验证。结果表明：所提出的多阶段模型能够兼顾物资分配的效率与公平，最大程度地降低物资短缺的延迟损失以及物资分配的总成本；运用灾民物资需求的比例短缺量化公平，避免了由于各受灾点的需求量差异而对公平分配产生的影响，可以使各受灾点即使在应急救援初期物资有限、中期物资持续供不应求等情况下，仍然能够在每阶段获得一定比率的所需物资，进而避免较大的物资短缺损失，确保多受灾点之间多阶段应急物资分配的公平性，更符合灾害救援实际，可为现实大规模灾害应急救援物资多阶段分配提供决策支持。

关键词: 应急物资分配, 集散点, 配送中心, 受灾点, 多阶段, 比例短缺

Abstract: Frequent disasters pose a great threat to human survival and social development, and pose challenges to the government's emergency response and disaster rescue. The key to effectively reduce the post-disaster losses and casualties lies in the scientific and equitable allocation of emergency relief materials. Therefore, how to quickly meet emergency material needs of disaster areas and reduce disaster losses through an effective emergency material allocation scheme is a realistic problem in the field of emergency management. Disasters usually cause multiple disaster sites, and their demand for different materials in different emergency stages changes dynamically in real time, resulting in the traditional static single-stage model may not meet the dynamic multi-stage allocation requirements of emergency materials. Based on this, a dynamic multi-stage allocation model for emergency materials based on multiple distribution centers, multiple supply sites and multiple disaster-affected sites is constructed by introducing an exponential utility function, considering the dynamic change characteristics of demands for different emergency materials at different stages, and combining the principle of efficiency and equity. The efficiency target minimizes the total costs that are produced by allocating all materials to all disaster sites during all stages, and the equity target minimizes the total loss that is produced by unsatisfied material demands during all stages, for achieving equitable allocation of materials among multiple affected sites. Then, the objective transformation and linear approximation method is used to solve the proposed model. For each disaster site m∈M, material n∈N and stage k∈K, create a set of "breakpoints" B_mnk, which are values at which the utility function will be (under)-approximated. A new variable μ_mn^k is introduced to represent the value of the utility function. Then the nonlinearity can be replaced/approximated in the objective function with the new objective function, as long as the following constraints are added:μ_mn^k ≥ γ(g)+γ'(g)(P_mn^k-g), ∀ m∈M,n∈N,k∈K,g∈B_mn^k. Finally, the validity and feasibility of the proposed model is verified through designing numerical examples and solving. The results indicate that the proposed model can consider both efficiency and fairness of material allocation, and can minimize the delay loss of material shortage and the total cost of material allocation. Moreover, quantifying the equity by using the proportional shortage of material demand of disaster victims, can avoid the impact on the fair allocation caused by the difference of demand among the disaster sites. This model can make the disaster sites obtain a certain ratio of materials needed at each stage even the supplies are limited or supplies are in short supply in the initial stage of emergency relief. Thus avoiding large material shortfalls and losses, ensuring fairness of multi-stage allocation of emergency materials among multiple disaster-stricken points are more in line with the reality of disaster relief. In addition, the proposed model, results and insights can provide decision support for the allocation of emergency relief materials in large-scale disasters, thereby developing effective allocation strategies according to different contexts.

Key words: emergency material allocation, distribution centers, supply sites, disaster-affected sites, multi-stage, percentage shortfall

中图分类号:

王妍妍, 孙佰清. 多受灾点应急物资动态多阶段分配模型研究[J]. 中国管理科学, 2019, 27(10): 138-147.

WANG Yan-yan, SUN Bai-qing. Dynamic Multi-stage Allocation Model of Emergency Materials for Multiple Disaster Sites[J]. Chinese Journal of Management Science, 2019, 27(10): 138-147.

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