本德分解
分解
Cone(正式语言)
二阶锥规划
订单(交换)
计算机科学
整数规划
数学优化
网络规划与设计
运筹学
数学
业务
算法
电信
生态学
几何学
财务
凸优化
正多边形
生物
作者
Qingmi Hu,Shaolong Hu,Zhijie Dong,Yongjia Song
标识
DOI:10.1016/j.ejor.2025.04.030
摘要
• Evacuation network design with road capacity improvement and uncertainty is stated. • A non-convex mixed-integer nonlinear program model is established. • Second-order cone programming reformulations are developed. • Benders decomposition with various acceleration strategies is devised. • Efficiency of proposed methods and comparison of existing method are explored. This work first presents a stochastic shelter location and evacuation planning problem with considering road capacity improvement strategies, in which the fixed setup cost of shelters and the improvement cost of road capacity are subject to a budget limit. To explicitly capture the impact of traffic volumes and road capacity improvement decisions on evacuation time, the Bureau of Public Roads function is employed. The problem is formulated as a non-convex mixed-integer nonlinear program (MINLP) model that is difficult to solve directly since the objective function is a multivariable non-convex nonlinear function. To tackle the non-convex MINLP, second-order cone programming (SOCP) reformulations that can be directly solved by using the state-of-the-art solvers are developed. Furthermore, a Benders decomposition (BD) approach that utilizes duality results of SOCP and employs acceleration strategies associated with valid inequalities, multi-cut, strengthened Benders cuts, knapsack inequalities, and callback routine, is proposed to solve large-scale problems. Moreover, extensive numerical experiments and a real-world case study (a potential hurricane risk zone in Texas, U.S.) are conducted to verify the applicability and effectiveness of the proposed model and solution approaches. Computational results show that the derived reformulations are competitive in dealing with small- and medium-scale problems, whereas BD approach demonstrates the best computational performance in solving large-scale problems. The devised acceleration strategies are effective in improving the computational efficiency of the BD approach. In addition, exerting investment for those shelters and arcs that are close to evacuation regions is useful to reduce the expected total evacuation time.
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