TRAFFIC PERFORMANCE ANALYSIS OF ROAD NETWORK BASED ON DYNAMIC USER EQUILIBRIUM

During the last two decades, Continuous Network Design Problem (CNDP) has received much more attention because of increasing trend of traffic congestion in road networks. In the CNDP, the problem is to find optimal link capacity expansions by minimizing the sum of total travel time and investment cost of capacity expansions in a road network. Considering both increasing traffic congestion and limited budgets of local authorities, the CNDP deserves to receive more attention in order to use available budget economically and to mitigate traffic congestion. The CNDP can generally be formulated as bilevel programming model in which the upper level deals with finding optimal link capacity expansions, whereas at the lower level, User Equilibrium (UE) link flows are determined by Wardrop’s first principle. In this paper, cuckoo search (CS) algorithm with Lévy flights is introduced for finding optimal link capacity expansions because of its recent successful applications in solving such complex problems. CS is applied to the 16-link and Sioux Falls networks and compared with available methods in the literature. Results show the potential of CS for finding optimal or near optimal link capacity expansions in a given road network.

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A Simultaneous Solution for Reserve Capacity Maximization and Delay Minimization Problems in Signalized Road Networks

Journal of Advanced Transportation ◽

10.1155/2019/6203137 ◽

2019 ◽

Vol 2019 ◽

pp. 1-18 ◽

Cited By ~ 1

Author(s):

Ozgur Baskan ◽

Huseyin Ceylan ◽

Cenk Ozan

Keyword(s):

Bilevel Programming ◽

Road Network ◽

Programming Model ◽

Numerical Test ◽

User Equilibrium ◽

Reserve Capacity ◽

Delay Minimization ◽

Weighted Sum Method ◽

Capacity Maximization ◽

Bilevel Programming Model

In this study, we present a bilevel programming model in which upper level is defined as a biobjective problem and the lower level is considered as a stochastic user equilibrium assignment problem. It is clear that the biobjective problem has two objectives: the first maximizes the reserve capacity whereas the second minimizes performance index of a road network. We use a weighted-sum method to determine the Pareto optimal solutions of the biobjective problem by applying normalization approach for making the objective functions dimensionless. Following, a differential evolution based heuristic solution algorithm is introduced to overcome the problem presented by use of biobjective bilevel programming model. The first numerical test is conducted on two-junction network in order to represent the effect of the weighting on the solution of combined reserve capacity maximization and delay minimization problem. Allsop & Charlesworth’s network, which is a widely preferred road network in the literature, is selected for the second numerical application in order to present the applicability of the proposed model on a medium-sized signalized road network. Results support authorities who should usually make a choice between two conflicting issues, namely, reserve capacity maximization and delay minimization.

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An Iterative Algorithm to Determine the Dynamic User Equilibrium in a Traffic Simulation Model

International Journal of Modern Physics C ◽

10.1142/s0129183198000303 ◽

1998 ◽

Vol 09 (03) ◽

pp. 393-407 ◽

Cited By ~ 104

Author(s):

C. Gawron

Keyword(s):

Probability Distribution ◽

Simulation Model ◽

Iterative Algorithm ◽

Traffic Simulation ◽

User Equilibrium ◽

Dynamic User Equilibrium ◽

Queuing Model ◽

Travel Costs ◽

Dynamic Version ◽

The Stability

An iterative algorithm to determine the dynamic user equilibrium with respect to link costs defined by a traffic simulation model is presented. Each driver's route choice is modeled by a discrete probability distribution which is used to select a route in the simulation. After each simulation run, the probability distribution is adapted to minimize the travel costs. Although the algorithm does not depend on the simulation model, a queuing model is used for performance reasons. The stability of the algorithm is analyzed for a simple example network. As an application example, a dynamic version of Braess's paradox is studied.

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