Abstract
This paper addresses the edge coloring by total labeling graph problem. This is a labeling of the vertices and edges of a graph such that the weights (colors) of the edges, defined by the sum of its label and the labels of its two endpoints, determine a proper edge coloring of the graph. We propose two integer programming formulations and derive valid inequalities which are added as cutting planes on a Branch-and-Cut framework. In order to improve the efficiency of the algorithm, we also develop initial and primal heuristics. The algorithm is tested on random instances and the computational results show that it is very effective in comparison with CPLEX. It is displayed that it reduces both the CPU time (for solved instances) and the final percentage gap (for unsolved instances), and that it is capable of solving instances that are out of the reach of CPLEX.
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Notes
Vertices are ordered according to the standard order on the natural numbers.
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This research was partially supported by UBACYT Grant 2014-2017 20020130100467BA.
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Borghini, F., Méndez-Díaz, I. & Zabala, P. An exact algorithm for the edge coloring by total labeling problem. Ann Oper Res 286, 11–31 (2020). https://doi.org/10.1007/s10479-018-2977-x
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DOI: https://doi.org/10.1007/s10479-018-2977-x