Operational Research and Optimization are fundamental disciplines which, for decades, provided the real-world with tools for solving practical problems. Many such problems arise in container ports. Container terminals are important assets in modern economies. They constitute an important means of distributing goods made overseas to domestic markets in most countries. They are expensive to build and difficult to operate. We describe here some of the main operations which are faced daily by decision makers at those facilities. Decision makers often use Operational Research and Optimization tools to run these operations effectively. In this thesis, we focus on seaside operations which can be divided into three main problems:udud1- the Berth Allocation Problem (BAP),ud2- the Quay Crane Assignment Problem (QCAP),ud3- the Quay Crane Scheduling Problem (QCSP).ududEach one of the above is a complex optimization problem in its own right. However, solving them individually without the consideration of the others may lead to overall suboptimal solutions. For this reason we will investigate the pairwise combinations of these problems and their total integration In addition, several important factors that affected on the final solution. The main contributions of this study are modelling and solving of the:udud1- Robust berth allocation problem (RBAP): a new efficient mathematical model is formulated and a hybrid algorithm based on Branch-and-Cut and the Genetic Algorithm is used to find optimal or near optimal solutions for large scale instances in reasonable time.ud2- Quay crane assignment and quay crane scheduling problem (QCASP): a new mathematical model is built to simultaneously solve QCASP and a heuristic based on the Genetic Algorithm is developed to find solutions to realistic instances in reasonable time.ud3- Berth allocation, quay crane assignment and quay crane scheduling problem (BACASP): an aggregate model for all three seaside operations is proposed and to solve realistic instances of the problem, an adapted variant of the Genetic Algorithm is implemented.ududKeywords: berth allocation; quay crane assignment; quay crane scheduling; terminal operations; genetic algorithm
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机译:运筹学和优化是基础学科,几十年来,它们为现实世界提供了解决实际问题的工具。在集装箱港口中会出现许多这样的问题。集装箱码头是现代经济中的重要资产。它们是将海外生产的商品分销到大多数国家的国内市场的重要手段。它们的建造昂贵且难以操作。我们在这里描述了决策者在这些设施中每天面临的一些主要操作。决策者经常使用运筹学和优化工具有效地运行这些运维。本文主要研究海上作业,主要分为三个主要问题: ud ud1-泊位分配问题(BAP), ud2-码头起重机分配问题(QCAP), ud3-码头起重机调度问题(QCSP)。 ud ud以上各项之一本身就是一个复杂的优化问题。但是,在不考虑其他因素的情况下单独解决它们可能会导致总体上不理想的解决方案。因此,我们将研究这些问题的成对组合及其总集成度。此外,一些影响最终解决方案的重要因素。这项研究的主要贡献是对 ud ud1-鲁棒泊位分配问题(RBAP)的建模和求解:建立了一个新的高效数学模型,并使用了基于分支剪切和遗传算法的混合算法 ud2-码头起重机分配和码头起重机调度问题(QCASP):建立了同时求解QCASP的新数学模型,并开发了基于遗传算法的启发式算法 ud3-泊位分配,码头起重机分配和码头起重机调度问题(BACASP):提出了针对所有三个海边作业的集合模型,并解决了问题的现实情况,这是一种经过改进的变体 ud ud关键字:泊位分配;码头起重机作业;码头起重机调度;终端操作;遗传算法
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