Two meta-heuristics for solving the multi-vehicle multi-covering tour problem with a constraint on the number of vertices

Authors

  • Manel Kammoun MODILS, Faculty of Economic Sciences and Management of Sfax, Sfax, Tunisie
  • Houda Derbel MODILS, Faculty of Economic Sciences and Management of Sfax, Sfax, Tunisie
  • Bassem Jarboui Higher Colleges of Technology, Abu Dhabi, UAE

DOI:

https://doi.org/10.2298/YJOR200115014K

Keywords:

Covering tour problem, multi-vehicle multi-covering tour problem, general variable neighborhood search algorithm, genetic algorithm, variable neighborhood descent

Abstract

In this work we deal with a generalized variant of the multi-vehicle covering tour problem (m-CTP). The m-CTP consists of minimizing the total routing cost and satisfying the entire demand of all customers, without the restriction of visiting them all, so that each customer not included in any route is covered. In the m-CTP, only a subset of customers is visited to fulfil the total demand, but a restriction is put on the length of each route and the number of vertices that it contains. This paper tackles a generalized variant of the m-CTP, called the multi-vehicle multi-covering Tour Problem (mm-CTP), where a vertex must be covered several times instead of once. We study a particular case of the mm-CTP considering only the restriction on the number of vertices in each route and relaxing the constraint on the length (mm-CTP-p). A hybrid metaheuristic is developet by combining Genetic Algorithm (GA), Variable Neighborhood Descent method (VND), and a General Variable Neighborhood Search algorithm (GVNS) to solve the problem. Computational experiments show that our approaches are competitive with the Evolutionary Local Search (ELS) and Genetic Algorithm (GA), the methods proposed in the literature.

References

Labbé, M. and Laporte, G. “Maximizing user convenience and postal service efficiency in post box location”, Belgian Journal of Operations Research, Statistics and Computer Science, 26 (1986) 21—35.

Simms, J.C. “Fixed and mobile facilities in dairy practice”, Veterinary Clinics North Am. Food Animal Practice, 5 (1989) 591—601.

Hodgson, M.J., Laporte, G. and Semet, F. “A covering tour model for planning mobile health care facilities in Suhum district Ghana”, Journal of Regional Science, 38 (1998) 621—638.

Doerner, K.F., Hartl, R.-F. “Health care logistics, emergency preparedness and disaster relief: New challenges for routing problems with a focus on the Austrian situation”, The Vehicle Routing Problem: Latest Advances and New Challenges, Springer, Boston, MA (2008) 527—550.

Current, J. “Multiobjective Design of Transportation Networks”, PhD dissertation. Johns Hopkins University (1981).

Gendreau, M., Laporte, G. and Semet, F. “The covering tour problem”, Operations Research, 45 (1997) 568—576.

Baldacci, R., Hadjiconstantinou, E. and Mingozzi, A. “An exact algorithm for the capacitated vehicle routing problem based on a two-commodity network flow formulation”, Operations Research, 52 (2004) 723—738.

Hachicha, M., Hodgson, M.J., Laporte, G. and Semet, F. “Heuristics for the multi-vehicle covering tour problem”, Computers and Operations Research, 27 (2000) 29—42.

Jozefowiez, N. “A branch-and-price algorithm for the multi-vehicle covering tour problem”, Networks, 64 (3) (2014) 160—168.

Hà, M.H., Bostel, N., Langevin, A. and Rousseau, L.-M. “An exact algorithm and a metaheuristic for the generalized vehicle routing problem with flexible fleet size”, Computers and Operations Research, 43 (2014) 9—19.

Kammoun, M., Derbel, H., Ratli, M. and Jarboui, B. “An integration of mixed VND and VNS: the case of the multivehicle covering tour problem”, International Transactions in Operational Research, 23 (3) (2017) 663—379.

Kammoun, M., Derbel, H., Ratli, M. and Jarboui, B. “A variable neighborhood search for solving the multi-vehicle covering tour problem”, Electronics Notes in Discrete Mathematics, 47 (2015) 285—292.

Pham, T.A., Hà, M.H. and Nguyen, X.H. “Solving the multi-vehicle multi-covering tour problem”, Computers and Operations Research, 88 (2017) 258–278.

Golden, B., NajiAzimi, Z., Raghavan, S., Salari, M. and Toth, P. “The generalized covering salesman problem”, INFORMS Journal on Computing, 24 (2012) 534—553.

Vidal, T., Crainic, T.G., Gendreau, M. and Prins, C. “A hybrid genetic algorithm with adaptive diversity management for a large class of vehicle routing problems with time windows”, Computers and Operations Research, 40 (1) (2013) 475–489.

Holland, J. Adaptation in Natural and Artificial Systems, University of Michigan Press, Ann Arbor, MI, 1975.

Mladenovic, N. and Hansen, P. “Variable neighborhood search”, Computers and Operations Research, 24 (11) (1997) 1097–1100.

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Published

2021-08-01

Issue

Vol. 31 No. 3 (2021)

Section

Research Articles

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