Optimización de Rutas basadas en Soft Computing para Movilidad Inteligente

La movilidad y transporte de pasajeros y mercancías es uno de los principales desafíos para el desarrollo de islas, ciudades y territorios. La prosperidad, competitividad y sostenibilidad de múltiples áreas económicas se ven afectadas por la movilidad. El crecimiento de la población, la capacidad limitada de los sistemas e infraestructuras de transporte y el impacto medioambiental del transporte fuerza a los territorios en el desarrollo de una movilidad sostenible y efectiva. En este complejo escenario, un territorio con una gestión del transporte y movilidad sostenible y eficiente ofrece a los ciudadanos una mejor calidad de vida. La transformación digital y las TIC impulsan la mejora de los servicios de movilidad para los ciudadanos, ayudan a gestionar correctamente la demanda en las redes de transporte y generan valor económico y ambiental. El surgimiento de la movilidad inteligente integra el sistema de transporte, las infraestructuras y las tecnologías para hacer que el transporte de pasajeros y mercancías sea eficiente, accesible, más seguro y limpio. Por lo tanto, las estrategias de movilidad inteligente deben ser capaces de proporcionar beneficios económicos y ambientales tangibles y mejorar la calidad del transporte de mercancías y pasajeros. Significa tomar acciones en múltiples frentes; gestión eficiente de la carga y la movilidad de pasajeros, reducción del impacto medioambiental, mejora de la planificación y la eficiencia del transporte público, reducción de la congestión, optimización del uso de la infraestructura física, entre otros. Una de las operaciones clave para los servicios de movilidad es la planificación de rutas. Esta actividad operativa incluye principalmente dos modos de transporte, mercancías y pasajeros. La mayoría de los transportes de mercancías y pasajeros se realizan a través de transporte por carretera. Las decisiones tomadas con respecto a las operaciones de planificación de rutas afectan económica y ambientalmente, y en general a la calidad de vida de los ciudadanos en los territorios en los que se desarrollan. Las operaciones de planificación de rutas se pueden optimizar para mejorar diferentes aspectos como la calidad del servicio, costes y flexibilidad del mismo, consumo de energía, impacto medioambiental, sostenibilidad, entre otros. La tarea de abordar las operaciones de planificación de rutas da lugar a la aparición de complejos problemas de optimización combinatoria que requieren considerar múltiples requisitos, restricciones, fuentes de información, entre otros. En la mayoría de los casos, estos problemas de optimización se clasifican como NP-duros con respecto a su complejidad computacional. Esta clase de problemas requiere enfoques de optimización eficientes y estrategias inteligentes para obtener soluciones de alta calidad y evitar grandes tiempos de cálculo. En este sentido, los enfoques de optimización aproximados, como las heurísticas y metaheurísticas, y las técnicas inteligentes inherentes a la Inteligencia Artificial y la Soft Computing han demostrado ser métodos efectivos y eficientes para resolver complejos problemas de planificación de rutas. Esta tesis presentada en la modalidad de compendio de publicaciones tiene como objetivo diseñar, implementar y validar procedimientos de optimización simples, eficientes y flexibles basados ​​en Inteligencia Artificial y Soft Computing dedicados a mejorar las soluciones de planificación de rutas en los contextos de transporte de mercancías, planificación personalizada de rutas turísticas y transporte eco-eficiente de residuos reciclables. Se han propuesto varios enfoques de solución para resolver problemas como Vehicle Routing Problem with Time Windows, Periodic Vehicle Routing Problem with Time Windows, Team Orienteering Problem with Time Windows, Tourist Trip Design Problem y variantes del mundo real y nuevas extensiones de los problemas mencionados. La calidad del servicio, la orientación al cliente, la imprecisión e incertidumbre en la información y la ecoeficiencia son criterios considerados en los problemas de planificación de rutas identificados. Los experimentos computacionales han demostrado que los métodos y técnicas propuestos son adecuados para obtener soluciones de alta calidad en tiempos computacionales cortos y pueden incorporarse como módulos en sistemas de transporte inteligentes

A flexible metaheuristic framework for solving rich vehicle routing problems

Route planning is one of the most studied research topics in the operations research area. While the standard vehicle routing problem (VRP) is the classical problem formulation, additional requirements arising from practical scenarios such as time windows or vehicle compartments are covered in a wide range of so-called rich VRPs. Many solution algorithms for various VRP variants have been developed over time as well, especially within the class of so-called metaheuristics. In practice, routing software must be tailored to the business rules and planning problems of a specific company to provide valuable decision support. This also concerns the embedded solution methods of such decision support systems. Yet, publications dealing with flexibility and customization of VRP heuristics are rare. To fill this gap this thesis describes the design of a flexible framework to facilitate and accelerate the development of custom metaheuristics for the solution of a broad range of rich VRPs. The first part of the thesis provides background information to the reader on the field of vehicle routing problems and on metaheuristic solution methods - the most common and widely-used solution methods to solve VRPs. Specifically, emphasis is put on methods based on local search (for intensification of the search) and large neighborhood search (for diversification of the search), which are combined to hybrid methods and which are the foundation of the proposed framework. Then, the main part elaborates on the concepts and the design of the metaheuristic VRP framework. The framework fulfills requirements of flexibility, simplicity, accuracy, and speed, enforcing the structuring and standardization of the development process and enabling the reuse of code. Essentially, it provides a library of well-known and accepted heuristics for the standard VRP together with a set of mechanisms to adapt these heuristics to specific VRPs. Heuristics and adaptation mechanisms such as templates for user-definable checking functions are explained on a pseudocode level first, and the most relevant classes of a reference implementation using the Microsoft .NET framework are presented afterwards. Finally, the third part of the thesis demonstrates the use of the framework for developing problem-specific solution methods by exemplifying specific customizations for five rich VRPs with diverse characteristics, namely the VRP with time windows, the VRP with compartments, the split delivery VRP, the periodic VRP, and the truck and trailer routing problem. These adaptations refer to data structures and neighborhood search methods and can serve as a source of inspiration to the reader when designing algorithms for new, so far unstudied VRPs. Computational results are presented to show the effectiveness and efficiency of the proposed framework and methods, which are competitive with current state-of-the-art solvers of the literature. Special attention is given to the overall robustness of heuristics, which is an important aspect for practical application

Dynamic vehicle routing problems: Three decades and counting

Since the late 70s, much research activity has taken place on the class of dynamic vehicle routing problems (DVRP), with the time period after year 2000 witnessing a real explosion in related papers. Our paper sheds more light into work in this area over more than 3 decades by developing a taxonomy of DVRP papers according to 11 criteria. These are (1) type of problem, (2) logistical context, (3) transportation mode, (4) objective function, (5) fleet size, (6) time constraints, (7) vehicle capacity constraints, (8) the ability to reject customers, (9) the nature of the dynamic element, (10) the nature of the stochasticity (if any), and (11) the solution method. We comment on technological vis-à-vis methodological advances for this class of problems and suggest directions for further research. The latter include alternative objective functions, vehicle speed as decision variable, more explicit linkages of methodology to technological advances and analysis of worst case or average case performance of heuristics.© 2015 Wiley Periodicals, Inc

Investigating heuristic and meta-heuristic algorithms for solving pickup and delivery problems

The development of effective decision support tools that can be adopted in the transportation industry is vital in the world we live in today, since it can lead to substantial cost reduction and efficient resource consumption. Solving the Vehicle Routing Problem (VRP) and its related variants is at the heart of scientific research for optimizing logistic planning. One important variant of the VRP is the Pickup and Delivery Problem (PDP). In the PDP, it is generally required to find one or more minimum cost routes to serve a number of customers, where two types of services may be performed at a customer location, a pickup or a delivery. Applications of the PDP are frequently encountered in every day transportation and logistic services, and the problem is likely to assume even greater prominence in the future, due to the increase in e-commerce and Internet shopping. In this research we considered two particular variants of the PDP, the Pickup and Delivery Problem with Time Windows (PDPTW), and the One-commodity Pickup and Delivery Problem (1-PDP). In both problems, the total transportation cost should be minimized, without violating a number of pre-specified problem constraints. In our research, we investigate heuristic and meta-heuristic approaches for solving the selected PDP variants. Unlike previous research in this area, though, we try to focus on handling the difficult problem constraints in a simple and effective way, without complicating the overall solution methodology. Two main aspects of the solution algorithm are directed to achieve this goal, the solution representation and the neighbourhood moves. Based on this perception, we tailored a number of heuristic and meta-heuristic algorithms for solving our problems. Among these algorithms are: Genetic Algorithms, Simulated Annealing, Hill Climbing and Variable Neighbourhood Search. In general, the findings of the research indicate the success of our approach in handling the difficult problem constraints and devising simple and robust solution mechanisms that can be integrated with vehicle routing optimization tools and used in a variety of real world applicationsEThOS - Electronic Theses Online ServiceGBUnited Kingdo

Investigating heuristic and meta-heuristic algorithms for solving pickup and delivery problems

The development of effective decision support tools that can be adopted in the transportation industry is vital in the world we live in today, since it can lead to substantial cost reduction and efficient resource consumption. Solving the Vehicle Routing Problem (VRP) and its related variants is at the heart of scientific research for optimizing logistic planning. One important variant of the VRP is the Pickup and Delivery Problem (PDP). In the PDP, it is generally required to find one or more minimum cost routes to serve a number of customers, where two types of services may be performed at a customer location, a pickup or a delivery. Applications of the PDP are frequently encountered in every day transportation and logistic services, and the problem is likely to assume even greater prominence in the future, due to the increase in e-commerce and Internet shopping. In this research we considered two particular variants of the PDP, the Pickup and Delivery Problem with Time Windows (PDPTW), and the One-commodity Pickup and Delivery Problem (1-PDP). In both problems, the total transportation cost should be minimized, without violating a number of pre-specified problem constraints. In our research, we investigate heuristic and meta-heuristic approaches for solving the selected PDP variants. Unlike previous research in this area, though, we try to focus on handling the difficult problem constraints in a simple and effective way, without complicating the overall solution methodology. Two main aspects of the solution algorithm are directed to achieve this goal, the solution representation and the neighbourhood moves. Based on this perception, we tailored a number of heuristic and meta-heuristic algorithms for solving our problems. Among these algorithms are: Genetic Algorithms, Simulated Annealing, Hill Climbing and Variable Neighbourhood Search. In general, the findings of the research indicate the success of our approach in handling the difficult problem constraints and devising simple and robust solution mechanisms that can be integrated with vehicle routing optimization tools and used in a variety of real world applicationsEThOS - Electronic Theses Online ServiceGBUnited Kingdo

Investigating heuristic and meta-heuristic algorithms for solving pickup and delivery problems

The development of effective decision support tools that can be adopted in the transportation industry is vital in the world we live in today, since it can lead to substantial cost reduction and efficient resource consumption. Solving the Vehicle Routing Problem (VRP) and its related variants is at the heart of scientific research for optimizing logistic planning. One important variant of the VRP is the Pickup and Delivery Problem (PDP). In the PDP, it is generally required to find one or more minimum cost routes to serve a number of customers, where two types of services may be performed at a customer location, a pickup or a delivery. Applications of the PDP are frequently encountered in every day transportation and logistic services, and the problem is likely to assume even greater prominence in the future, due to the increase in e-commerce and Internet shopping. In this research we considered two particular variants of the PDP, the Pickup and Delivery Problem with Time Windows (PDPTW), and the One-commodity Pickup and Delivery Problem (1-PDP). In both problems, the total transportation cost should be minimized, without violating a number of pre-specified problem constraints. In our research, we investigate heuristic and meta-heuristic approaches for solving the selected PDP variants. Unlike previous research in this area, though, we try to focus on handling the difficult problem constraints in a simple and effective way, without complicating the overall solution methodology. Two main aspects of the solution algorithm are directed to achieve this goal, the solution representation and the neighbourhood moves. Based on this perception, we tailored a number of heuristic and meta-heuristic algorithms for solving our problems. Among these algorithms are: Genetic Algorithms, Simulated Annealing, Hill Climbing and Variable Neighbourhood Search. In general, the findings of the research indicate the success of our approach in handling the difficult problem constraints and devising simple and robust solution mechanisms that can be integrated with vehicle routing optimization tools and used in a variety of real world application

Tactical Vehicle Routing Planning with Application to Milk Collection and Distribution

De nombreux problèmes pratiques qui se posent dans dans le domaine de la logistique, peuvent être modélisés comme des problèmes de tournées de véhicules. De façon générale, cette famille de problèmes implique la conception de routes, débutant et se terminant à un dépôt, qui sont utilisées pour distribuer des biens à un nombre de clients géographiquement dispersé dans un contexte où les coûts associés aux routes sont minimisés. Selon le type de problème, un ou plusieurs dépôts peuvent-être présents. Les problèmes de tournées de véhicules sont parmi les problèmes combinatoires les plus difficiles à résoudre. Dans cette thèse, nous étudions un problème d’optimisation combinatoire, appartenant aux classes des problèmes de tournées de véhicules, qui est liée au contexte des réseaux de transport. Nous introduisons un nouveau problème qui est principalement inspiré des activités de collecte de lait des fermes de production, et de la redistribution du produit collecté aux usines de transformation, pour la province de Québec. Deux variantes de ce problème sont considérées. La première, vise la conception d’un plan tactique de routage pour le problème de la collecte-redistribution de lait sur un horizon donné, en supposant que le niveau de la production au cours de l’horizon est fixé. La deuxième variante, vise à fournir un plan plus précis en tenant compte de la variation potentielle de niveau de production pouvant survenir au cours de l’horizon considéré. Dans la première partie de cette thèse, nous décrivons un algorithme exact pour la première variante du problème qui se caractérise par la présence de fenêtres de temps, plusieurs dépôts, et une flotte hétérogène de véhicules, et dont l’objectif est de minimiser le coût de routage. À cette fin, le problème est modélisé comme un problème multi-attributs de tournées de véhicules. L’algorithme exact est basé sur la génération de colonnes impliquant un algorithme de plus court chemin élémentaire avec contraintes de ressources. Dans la deuxième partie, nous concevons un algorithme exact pour résoudre la deuxième variante du problème. À cette fin, le problème est modélisé comme un problème de tournées de véhicules multi-périodes prenant en compte explicitement les variations potentielles du niveau de production sur un horizon donné. De nouvelles stratégies sont proposées pour résoudre le problème de plus court chemin élémentaire avec contraintes de ressources, impliquant dans ce cas une structure particulière étant donné la caractéristique multi-périodes du problème général. Pour résoudre des instances de taille réaliste dans des temps de calcul raisonnables, une approche de résolution de nature heuristique est requise. La troisième partie propose un algorithme de recherche adaptative à grands voisinages où de nombreuses nouvelles stratégies d’exploration et d’exploitation sont proposées pour améliorer la performances de l’algorithme proposé en termes de la qualité de la solution obtenue et du temps de calcul nécessaire.Many practical problems arising in real-world applications in the field of logistics can be modeled as vehicle routing problems (VRP). In broad terms, VRPs deal with designing optimal routes for delivering goods or services to a number of geographically scattered customers in a context in which, routing costs are minimized. Depending on the type of problem, one or several depots may be present. Routing problems are among the most difficult combinatorial optimization problems. In this dissertation we study a special combinatorial optimization problem, belonging to the class of the vehicle routing problem that is strongly linked to the context of the transportation networks. We introduce a new problem setting, which is mainly inspired by the activities of collecting milk from production farms and distributing the collected product to processing plants in Quebec. Two different variants of this problem setting are considered. The first variant seeks a tactical routing plan for the milk collection-distribution problem over a given planning horizon assuming that the production level over the considered horizon is fixed. The second variant aims to provide a more accurate plan by taking into account potential variations in terms of production level, which may occur during the course of a horizon. This thesis is cast into three main parts, as follows: In the first part, we describe an exact algorithm for the first variant of the problem, which is characterized by the presence of time windows, multiple depots, and a heterogeneous fleet of vehicles, where the objective is to minimize the routing cost. To this end, the problem is modeled as a multi-attribute vehicle routing problem. The exact algorithm proposed is based on the column generation approach, coupled with an elementary shortest path algorithm with resource constraints. In the second part, we design an exact framework to address the second variant of the problem. To this end, the problem is modeled as a multi-period vehicle routing problem, which explicitly takes into account potential production level variations over a horizon. New strategies are proposed to tackle the particular structure of the multi-period elementary shortest path algorithm with resource constraints. To solve realistic instances of the second variant of the problem in reasonable computation times, a heuristic approach is required. In the third part of this thesis, we propose an adaptive large neighborhood search, where various new exploration and exploitation strategies are proposed to improve the performance of the algorithm in terms of solution quality and computational efficiency