A multi-objective chemical reaction optimisation algorithm for multi-objective travelling salesman problem

被引：7

作者：

机构：

[1] Department of Fundamental Computer Science and its Applications, MISC Laboratory, Constantine 2 University, Route Ain El Bey, Constantine

来源：

Bouzoubia, Samira | 1600年 / Inderscience Enterprises Ltd., 29, route de Pre-Bois, Case Postale 856, CH-1215 Geneva 15, CH-1215, Switzerland卷 / 06期

关键词：

Bio-inspired algorithm; CRO; MOTSP; Multi-objective chemical reaction; Multi-objective optimisation; Multi-objective travelling salesman problem;

D O I：

10.1504/IJICA.2014.066498

中图分类号：

学科分类号：

摘要：

The multi-objective travelling salesman problem (MOTSP) is a well-known combinatorial optimisation problem that belongs to the class of NP-hard problems. The MOTSP plays an important role in computing theory and in many real life applications. Unfortunately, finding efficient MOTSP solutions is still a challenging problem. That is why several methods were proposed to deal with this problem. This paper proposes a new multi-objective chemical reaction optimisation (MOCRO) algorithm to solve MOTSP. To maintain the diversity of the solutions, MOCRO uses a non-dominated sorting procedure proposed in NSGA2. Two new variants of MOCRO are proposed to deal the MOTSP. The first is MOCRO based on amount of domination (MOCRO-Dom), while the second is MOCRO based on weighted sum (MOCRO-WS). The experimental results have shown the superior performance of MOCRO-Dom and MOCRO-WS compared to NSGA2. Moreover, a comparative study between MOCRO-Dom and MOCRO-WS and the impact of the major parameters on the performance has been investigated. Copyright © 2014 Inderscience Enterprises Ltd.

引用

页码：87 / 101

页数：14

共 41 条

[1]

Angel E., Bampis E., Gourves L., A dynasearch neighborhood for the bicriteria traveling salesman problem, Metaheuristics for Multiobjective Optimisation, LNEMS, 535, pp. 153-176, (2004)

[2]

Angus D., Crowding population-based ant colony optimisation for the multi-objective travelling salesman problem, IEEE Symposium on Computational Intelligence in Multicriteria Decision Making, pp. 333-340, (2007)

[3]

Bandyopadhyay S., Saha S., Maulik U., Deb K., A simulated annealing based multi-objective optimization algorithm: A mosa, IEEE Transactions on Evolutionary Computation, 12, 3, pp. 269-283, (2008)

[4]

Coello C.A.C., Van Veldhuizen D.A., Lamont G.B., Evolutionary Algorithms for Solving Multi-Objective Problems, 242, (2002)

[5]

Collette Y., Siarry P., Multi-objective Optimization Principals and Case Studies, (2003)

[6]

Deb K., Agrawal S., Pratab A., Meyarivan T., A fast elitist non-dominated sorting genetic algorithms for multi-objective optimization: NSGA-II kangal report 200001, Tech. Rep., Indian Institute of Technology, (2000)

[7]

Deb K., Pratap A., Agarwal S., Meyarivan T., A fast and elitist multi-objective genetic algorithm: NSGA-II, IEEE Transactions on Evolutionary Computation, 6, 2, pp. 182-197, (2002)

[8]

Dorigo M., Stutzle T., Ant Colony Optimization, (2004)

[9]

Elaoud S., Teghem J., Loukil T., Multiple crossover genetic algorithm for the multiobjective traveling salesman problem, International Symposium on Combinatorial Optimization, pp. 939-946, (2010)

[10]

Fischer R., Richter K., Solving a multiobjective traveling salesman problem by dynamic programming, Optimization, 13, 2, pp. 247-252, (1982)

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