Title :
A Hybrid Multiagent Learning Algorithm for Solving the Dynamic Simulation-Based Continuous Transit Network Design Problem
Author_Institution :
Transp. Econ. Lab., Univ. Lyon, Lyon, France
Abstract :
This paper proposes a hybrid multiagent learning algorithm for solving the dynamic simulation-based bilevel network design problem. The objective is to determine the optimal frequency of a multimodal transit network, which minimizes total users´ travel cost and operation cost of transit lines. The problem is formulated as a bilevel programming problem with equilibrium constraints describing non-cooperative Nash equilibrium in a dynamic simulation-based transit assignment context. A hybrid algorithm combing the cross entropy multiagent learning algorithm and Hooke-Jeeves algorithm is proposed. Computational results are provided on a small network to illustrate the performance of the proposed algorithm.
Keywords :
game theory; learning (artificial intelligence); multi-agent systems; traffic engineering computing; Hooke-Jeeves algorithm; bilevel programming problem; cross-entropy multiagent learning algorithm; dynamic simulation-based bilevel network design problem; dynamic simulation-based continuous transit network design problem; equilibrium constraints; hybrid multiagent learning algorithm; multimodal transit network; noncooperative Nash equilibrium; optimal frequency determination; Algorithm design and analysis; Entropy; Heuristic algorithms; Legged locomotion; Time frequency analysis; Vehicle dynamics; Vehicles; learning; multiagent; network design; simulation; transit system;
Conference_Titel :
Technologies and Applications of Artificial Intelligence (TAAI), 2011 International Conference on
Conference_Location :
Chung-Li
Print_ISBN :
978-1-4577-2174-8
DOI :
10.1109/TAAI.2011.27
