Multimodal network path optimization based on a two‐stage algorithm in the perspective of sustainable transport development

Cong Qiao, Ke Niu, Weina Ma
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Abstract

The environmental issues brought on by carbon emissions from transport have risen to prominence in recent years. More and more academics are using the multi‐objective path optimization method to solve the multimodal optimization problem from the standpoint of sustainable development in order to address the environmental issues brought on by the transport process. The research proposes a two‐stage method to handle multi‐objective optimization convergence and simplify multimodal transport path optimization. In the first stage, a fuzzy C clustering model is established, and based on the clustering results, the multimodal transport network nodes are identified. In the second stage, a multimodal transport multi‐objective path optimization model is established, and the optimal path is solved using a genetic algorithm. The research method was applied in the Bohai Rim region. Results indicated that the fuzzy C‐clustering method and the genetic method were able to select the optimal node city, thus solving the actual site selection problem of multimodal transportation networks. Using the FCM model, the 86 city nodes were categorized into four types, leading to the establishment of the most proficient multimodal transportation network in the Bohai Rim region. Using a genetic algorithm for optimization, a stable state is reached after 25 iterations. In the validation experiment on path optimization, the cost was reduced by 47.12% compared to the minimum single objective time, and transportation carbon emissions saw a reduction of 28.23%. Similarly, compared to the lowest target for transportation carbon emissions, the cost was reduced by 39.48% and the time was reduced by 38.12%. Compared to the lowest target for transportation carbon emissions, the time was reduced by 32.02% and the carbon emissions were reduced by 19.23%. Notably, the transportation multi‐objective path optimization model showed significant improvement compared to the single‐target model. The research method has been proven to be superior, and can offer the most optimal transportation route guidance for participants in multimodal transportation. Furthermore, it can effectively tackle the issue of node selection convergence and multi‐objective optimization, while also serving as a valuable source of data to support the theoretical advancement of multimodal transportation network path optimization.
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可持续交通发展视角下基于两阶段算法的多式联运网络路径优化
近年来,运输过程中的碳排放所带来的环境问题日益突出。越来越多的学者从可持续发展的角度出发,利用多目标路径优化方法解决多式联运优化问题,以解决运输过程带来的环境问题。本研究提出了一种分两个阶段处理多目标优化收敛和简化多式联运路径优化的方法。第一阶段,建立模糊 C 聚类模型,根据聚类结果确定多式联运网络节点。第二阶段,建立多式联运多目标路径优化模型,利用遗传算法求解最优路径。研究方法应用于环渤海地区。结果表明,模糊 C 聚类法和遗传方法能够选择最优节点城市,从而解决了多式联运网络的实际选址问题。利用 FCM 模型,将 86 个城市节点分为四种类型,从而建立了环渤海地区最完善的多式联运网络。利用遗传算法进行优化,经过 25 次迭代后达到稳定状态。在路径优化的验证实验中,与最小单一目标时间相比,成本降低了 47.12%,交通碳排放量减少了 28.23%。同样,与交通碳排放的最低目标相比,成本减少了 39.48%,时间减少了 38.12%。与交通碳排放的最低目标相比,时间减少了 32.02%,碳排放减少了 19.23%。值得注意的是,与单目标模型相比,交通多目标路径优化模型有了显著改善。该研究方法的优越性已得到证实,可为多式联运参与者提供最优化的交通路线指导。此外,它还能有效解决节点选择收敛和多目标优化问题,同时也为多式联运网络路径优化的理论研究提供了宝贵的数据支持。
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