Energy-Efficient Multi-Trip Routing for Municipal Solid Waste Collection by Contribution-Based Adaptive Particle Swarm Optimization

Xiaoning Shen;Hongli Pan;Zhongpei Ge;Wenyan Chen;Liyan Song;Shuo Wang
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Abstract

Waste collection is an important part of waste management system. Transportation costs and carbon emissions can be greatly reduced by proper vehicle routing. Meanwhile, each vehicle can work again after achieving its capacity limit and unloading the waste. For this, an energy-efficient multi-trip vehicle routing model is established for municipal solid waste collection, which incorporates practical factors like the limited capacity, maximum working hours, and multiple trips of each vehicle. Considering both economy and environment, fixed costs, fuel costs, and carbon emission costs are minimized together. To solve the formulated model effectively, contribution-based adaptive particle swarm optimization is proposed. Four strategies named greedy learning, multi-operator learning, exploring learning, and exploiting learning are specifically designed with their own searching priorities. By assessing the contribution of each learning strategy during the process of evolution, an appropriate one is selected and assigned to each individual adaptively to improve the searching efficiency of the algorithm. Moreover, an improved local search operator is performed on the trips with the largest number of waste sites so that both the exploiting ability and the convergence accuracy of the algorithm are improved. Performance of the proposed algorithm is tested on ten waste collection instances, which include one real-world case derived from the Green Ring Company of Jiangbei New District, Nanjing, China, and nine synthetic instances with increasing scales generated from the commonly-used capacitated vehicle routing problem benchmark datasets. Comparisons with five state-of-the-art algorithms show that the proposed algorithm can obtain a solution with a higher accuracy for the constructed model.
基于贡献自适应粒子群优化的城市生活垃圾高效多行程收集路径
垃圾收集是垃圾管理系统的重要组成部分。适当的车辆路线可以大大减少运输成本和碳排放。同时,每辆车在达到其容量极限并卸下废物后可以重新工作。为此,建立了城市生活垃圾收集的节能多行程车辆路径模型,该模型考虑了每辆车的有限容量、最大工作时间和多行程等实际因素。考虑到经济和环境,固定成本、燃料成本和碳排放成本一起最小化。为了有效求解该模型,提出了基于贡献的自适应粒子群优化算法。分别设计了贪心学习、多算子学习、探索学习和利用学习四种策略,各策略具有各自的搜索优先级。通过评估每种学习策略在进化过程中的贡献,自适应地为每个个体选择合适的学习策略,以提高算法的搜索效率。此外,在垃圾站点数量最多的行程上进行改进的局部搜索算子,提高了算法的挖掘能力和收敛精度。在10个垃圾收集实例上测试了算法的性能,其中包括来自中国南京江北新区绿环公司的一个真实案例,以及来自常用的有能力车辆路径问题基准数据集的9个随规模增加的合成实例。与五种最新算法的比较表明,该算法对所构建的模型具有较高的解精度。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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CiteScore
7.80
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