On the minimization of traffic congestion in road networks with tolls

Stefanello, Fernando; Buriol, Luciana S.; Hirsch, Michael J.; Pardalos, Pãnos M.; Querido, Tania; Resende, Maurício G. C.; Ritt, Marcus

doi:10.1007/s10479-015-1800-1

Cited by 39 publications

(16 citation statements)

References 19 publications

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“…These methods were chosen based on their successful results for a significant number of applications, such as Resende (), Stefanello et al. (), Reis et al. (), and Morán‐Mirabal et al.…”

Section: Methods For Urnd and Mrndmentioning

confidence: 99%

Model and methods to address urban road network problems with disruptions

Huang

Santos

Duhamel

2019

Int Trans Operational Res

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Disruptions in urban road networks can quickly and significantly reduce the quality of the whole transportation network, and impact urban mobility for light vehicles, public transportation, etc. In this study, we consider both unidirectional and multidirectional road network problems with disruptions and connecting requirements. These problems aim at reconfiguring the urban network in terms of road direction in order to maintain a path among all points of the network (strong connectivity). The former is defined on simple graphs, mainly modeling part of a city such as historical centers, while the latter relies on multigraphs, modeling more general networks. Restoring the network (strong connectivity) after some disruptions may require the modification of the orientation of some streets, that is, arc reversals. Such actions can disturb users' driving habits. Thus, two objectives are considered separately: minimizing the total travel distance and minimizing the number of arc reversals. We define formally both problems and propose two metaheuristics, a biased random key genetic algorithm and an iterated local search. Numerical experiments have been performed on a set of generated instances and on the urban network of Troyes (France).

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“…These methods were chosen based on their successful results for a significant number of applications, such as Resende (), Stefanello et al. (), Reis et al. (), and Morán‐Mirabal et al.…”

Section: Methods For Urnd and Mrndmentioning

confidence: 99%

Model and methods to address urban road network problems with disruptions

Huang

Santos

Duhamel

2019

Int Trans Operational Res

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“…Traffic flows are characterized by three properties [11]: traffic flow velocity, traffic flow density and traffic volume. Traffic flow velocity indicates the average speed of vehicles on the road, in units of km/h.…”

Section: Grey Relational Clustering Modelmentioning

confidence: 99%

A Method for Traffic Congestion Clustering Judgment Based on Grey Relational Analysis

Zhang

Wang

et al. 2016

IJGI

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Traffic congestion clustering judgment is a fundamental problem in the study of traffic jam warning. However, it is not satisfactory to judge traffic congestion degrees using only vehicle speed. In this paper, we collect traffic flow information with three properties (traffic flow velocity, traffic flow density and traffic volume) of urban trunk roads, which is used to judge the traffic congestion degree. We first define a grey relational clustering model by leveraging grey relational analysis and rough set theory to mine relationships of multidimensional-attribute information. Then, we propose a grey relational membership degree rank clustering algorithm (GMRC) to discriminant clustering priority and further analyze the urban traffic congestion degree. Our experimental results show that the average accuracy of the GMRC algorithm is 24.9% greater than that of the K-means algorithm and 30.8% greater than that of the Fuzzy C-Means (FCM) algorithm. Furthermore, we find that our method can be more conducive to dynamic traffic warnings.

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“…We verify that it is indeed an optimal flow using technique similar to the one used in Theorem 1. Specifically, under the optimal flow and with respect to the new cost functions, e (x) + x e (x): (i) h will cost 11B, (ii) for each i, a i and b i will cost 3 2 α i , c 1,i and c 2,i will cost 5 2 α i , and q i and g i will cost 4α i , which makes each path in G i costing 11 2 α i , and (iii) the cost of any path through the G i 's has cost n i=1 11 2 α i = 11B.…”

Section: Single-commodity Network With Linear Latencies and All Edgesmentioning

confidence: 99%

“…A comprehensive explanation is presented under Lemma 5. Fix cost on the right sub-tree, 2 ← lst (r,opt) ·p2· ; 8 Fix cost on the left sub-tree, 1 ← in − 2 ; 9 else 10 Fix cost on the sub-trees, 1 ← in , 2 ← in ; 11 Recur on root r 1 of first children T ·1, PLACETOLL (T ·1, 1 ) ; 12 Recur on root r 2 of second children T ·2, PLACETOLL (T ·2, 2 ) ; Algorithm 5: COMBINESERIES Input: Lists: lst 1 , lst 2 , lst. Output: Processed List: lst.…”

Section: Algorithm 1: Makelistplmentioning

confidence: 99%

“…Output: Processed List: lst. 1 Let l and r be the size of lst 1 and lst 2 respectively; 2 Length of maximum used path in the combined graph 3 max ← max{lst (1,0) · , lst (2,0) · }; 4 Min number of edges to induce max in G p for p ∈ {1, 2}, 5 s p ← min{lst (p,j) ·η : lst (p,j) · ≥ max } ; 6 Min number of edges in lst, s ← s 1 + s 2 ; 7 Max number of edges in lst, f ← lst (1,l) ·η + lst (2,r) ·η; 8 for i ← s to f do 9 Find the possible edge divisions for i, I = (j 1 , j 2 ) : lst (1,j1) ·η + lst (2,j2) ·η = i ; 10 Find the cost maximizing division; 11 (opt 1 , opt 2 ) = arg max (j1,j2)∈I min lst (1,j1) · , lst (2,j2) · ; 12 i ← min{lst (1,opt1) · , lst (2,opt2) · } ; 13 Create the new element α, (α·η, α· , α·p1, α·p2) ← i, i , lst (1,opt1) , lst (2,opt2) ; 14 Insert α in list lst;…”

Section: Algorithm 1: Makelistplmentioning

confidence: 99%

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New Complexity Results and Algorithms for the Minimum Tollbooth Problem

Basu

Lianeas

Nikolova

2015

Web and Internet Economics

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Abstract. The inefficiency of the Wardrop equilibrium of nonatomic routing games can be eliminated by placing tolls on the edges of a network so that the socially optimal flow is induced as an equilibrium flow. A solution where the minimum number of edges are tolled may be preferable over others due to its ease of implementation in real networks. In this paper we consider the minimum tollbooth (M IN T B) problem, which seeks social optimum inducing tolls with minimum support. We prove for single commodity networks with linear latencies that the problem is NP-hard to approximate within a factor of 1.1377 through a reduction from the minimum vertex cover problem. Insights from network design motivate us to formulate a new variation of the problem where, in addition to placing tolls, it is allowed to remove unused edges by the social optimum. We prove that this new problem remains NP-hard even for single commodity networks with linear latencies, using a reduction from the partition problem. On the positive side, we give the first exact polynomial solution to the M IN T B problem in an important class of graphs-series-parallel graphs. Our algorithm solves M IN T B by first tabulating the candidate solutions for subgraphs of the series-parallel network and then combining them optimally.

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On the minimization of traffic congestion in road networks with tolls

Cited by 39 publications

References 19 publications

Model and methods to address urban road network problems with disruptions

Model and methods to address urban road network problems with disruptions

A Method for Traffic Congestion Clustering Judgment Based on Grey Relational Analysis

New Complexity Results and Algorithms for the Minimum Tollbooth Problem

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