Modelo matemático para o projeto de redes cicloviárias integradas ao sistema de transporte público por ônibus em áreas urbanas /

Oliveira, Stefano Petrini

January 2020

Orientador: Antônio Fernando Branco Costa / Resumo: O presente trabalho desenvolveu um modelo matemático que contribui para o projeto de redes cicloviárias conexas e integradas ao sistema de transporte público por ônibus em áreas urbanas, fazendo uso da Otimização Multiobjetivo (OM) por meio da Programação Linear Inteira Mista (MILP ou MIP). A investigação dos critérios de infraestrutura que influenciam a demanda cicloviária e que deveriam compor a modelagem matemática foi realizada por meio da Revisão da Literatura e cinco critérios identificados, referentes ao: Conforto, Segurança, Objetividade, Intermodalidade e Continuidade. Cada critério é composto por uma série de subcritérios, dezesseis no total, classificados como parâmetros de projeto de entrada e/ou de saída para o modelo matemático, segundo funções objetivos e restrições. Uma aplicação do modelo foi realizada em um caso real para cidade de grande porte, em São José dos Campos – SP, e obtidas soluções exatas com redes parcialmente conexas (abordagem 1) e redes totalmente conexas (abordagem 2), integradas aos pontos de parada de ônibus e as linhas de ônibus da região delimitada, por meio da linguagem de modelagem General Algebric Modeling System (GAMS) e o solver CPLEX. Os resultados obtidos foram aderentes a realidade da macrozona de tráfego na região estudada e contribuem para o planejamento urbano como validado pela Secretaria de Mobilidade Urbana de São José dos Campos. A análise de diversos cenários para o modelo matemático, ponderando os objetivos do modelo, pos... (Resumo completo, clicar acesso eletrônico abaixo) / Abstract: The present work created a mathematical model that contributes to design bikeway networks integrated to the public transport service by buses in urban areas, using the Network Multiobjective Optimization through Mixed by means of Mixed Integer Linear Programming (MILP or MIP). The investigation of the infrastructure criteria that influence cycling demand and that should set the mathematical modeling was carried out through the Literature Review and five criteria were identified, referring to: Comfort, Safety, Objectivity, Intermodality and Connectivity. Each criteria is composed of a subcriteria set, sixteen in total, which performed as input and/or output design parameters for the mathematical model, according to fitness functions and constraints. An application of the model was carried out in a real case in São Jose dos Campos city - Sao Paulo state, and exact solutions were obtained with partially connected networks (approach 1) and fully connected networks (approach 2), integrated to the stop points by bus and bus lines in the defined region, using the General Algebric Modeling System (GAMS) modeling language and the CPLEX solver. The results obtained were adherent to the reality of the traffic macrozone in the studied region and contribute to urban planning, as validated by the São José dos Campos Urban Mobility Secretariat. The analysis of several scenarios for the mathematical model, considering the model's objectives, made it possible to verify the behavior of the res... (Complete abstract click electronic access below) / Doutor

Transit Network Design Problem

Integrated bikeway network

Mixed Integer Linear Programming

Public transport service by bus

Multiobjective Optimization

Rede cicloviária integrada

Programação Linear Inteira Mista

Otimização Multiobjetivo

Modelos matemáticos.

Ciclovias.

Transportes coletivos.

Otimização matemática.

Méthode de génération de colonnes pour les problèmes de conception de réseaux avec coûts d’ajout de capacité

El Filali, Souhaïla

05 1900

Les problèmes de conception de réseaux ont reçu un intérêt particulier et ont été largement étudiés de par leurs nombreuses applications dans différents domaines, tels que les transports et les télécommunications. Nous nous intéressons dans ce mémoire au problème de conception de réseaux avec coûts d’ajout de capacité. Il s’agit d’installer un ensemble d’équipements sur un réseau en vue de satisfaire la demande, tout en respectant les contraintes de capacité, chaque arc pouvant admettre plusieurs équipements. L’objectif est de minimiser les coûts variables de transport des produits et les coûts fixes d’installation ou d’augmentation de capacité des équipements. La méthode que nous envisageons pour résoudre ce problème est basée sur les techniques utilisées en programmation linéaire en nombres entiers, notamment celles de génération de colonnes et de coupes. Ces méthodes sont introduites dans un algorithme général de branch-and-bound basé sur la relaxation linéaire. Nous avons testé notre méthode sur quatre groupes d’instances de tailles différentes, et nous l’avons comparée à CPLEX, qui constitue un des meilleurs solveurs permettant de résoudre des problèmes d’optimisation, ainsi qu’à une méthode existante dans la littérature combinant des méthodes exactes et heuristiques. Notre méthode a été plus performante que ces deux méthodes, notamment pour les instances de très grandes tailles. / Network design problems received a particular interest and have been widely studied because of their many applications in different areas, such as logistics and telecommunications. We focus in this work on the multicommodity capacitated network design problem with capacity expansion costs. It consists in opening a set of facilities on a network in order to meet the demand of some commodities, while respecting the capacity constraints. Each arc can admit several facilities. The objective is to minimize the commodities transportation costs, and the fixed costs of opening or increasing the capacity of the facilities. The method we are using to solve this problem is based on techniques used in integer programming, including column generation and cutting-plane methods. These methods are introduced into a general branch-and-bound algorithm, based on linear relaxation. We test our method on four groups of instances of different sizes, and we compare it with CPLEX, which is one of the best solvers available for optimization problems. We compare it also with an existing method in the literature, combining exact and heuristic methods. Numerical results show that our method was able to outperform both methods, especially when tested on large scale instances.

Problème de conception de réseaux

Coûts d’ajout de capacité

Reformulation 0-1

Génération de colonnes

Méthodes de coupes

Branch-and-bound

Capacity expansion costs

0-1 reformulation

Column generation

Cutting-plane methods