We formulate the edge coloring problem on a simple graph as the integer program of covering edges by matchings. For the NP-hard case of 3-regular graphs we show that it is sufficient to solve the linear programming relaxation with the additional constraints hat each odd circuit be covered by at least three matchings. We give an efficient separation algorithm for recognizing violated odd circuit constraints and a linear programming based constrained weighted matching algorithm for pricing. Computational experiments with the overall linear programming system are presented
This paper considers the polyhedral results and the min–max results on packing and covering problems...
This chapter discusses polyhedral approaches in combinatorial optimization. Using a cutting-plane al...
AbstractWe present an approach based on integer programming formulations of the graph coloring probl...
We consider two (0,1)-linear programming formulations of the graph (vertex-) coloring problem, in wh...
AbstractWe consider two (0, 1)-linear programming formulations of the graph (vertex-) coloring probl...
A total coloring of a graph G = (V, E) is an assignment of colors to vertices and edges such that ne...
The polyhedral approach is one of the most powerful techniques available for solving hard combinator...
The polyhedral approach is one of the most powerful techniques available for solving hard combinator...
Combinatorial optimization problems appear in many disciplines ranging from management and logistics...
We consider the problem of covering the edges of a graph by a sequence of matchings subject to the c...
AbstractA coloring of a graph G is an assignment of colors to the vertices of G such that any two ve...
Combinatorial optimization problems arise in several areas ranging from management to mathematics an...
A linear programming (LP) approach is proposed for the weighted graph matching problem. A linear pro...
A coloring of the vertices of a graph G is convex if, for each assigned color d, the vertices with c...
In this paper we define a generalization of the classical vertex coloring problem of a graph, where ...
This paper considers the polyhedral results and the min–max results on packing and covering problems...
This chapter discusses polyhedral approaches in combinatorial optimization. Using a cutting-plane al...
AbstractWe present an approach based on integer programming formulations of the graph coloring probl...
We consider two (0,1)-linear programming formulations of the graph (vertex-) coloring problem, in wh...
AbstractWe consider two (0, 1)-linear programming formulations of the graph (vertex-) coloring probl...
A total coloring of a graph G = (V, E) is an assignment of colors to vertices and edges such that ne...
The polyhedral approach is one of the most powerful techniques available for solving hard combinator...
The polyhedral approach is one of the most powerful techniques available for solving hard combinator...
Combinatorial optimization problems appear in many disciplines ranging from management and logistics...
We consider the problem of covering the edges of a graph by a sequence of matchings subject to the c...
AbstractA coloring of a graph G is an assignment of colors to the vertices of G such that any two ve...
Combinatorial optimization problems arise in several areas ranging from management to mathematics an...
A linear programming (LP) approach is proposed for the weighted graph matching problem. A linear pro...
A coloring of the vertices of a graph G is convex if, for each assigned color d, the vertices with c...
In this paper we define a generalization of the classical vertex coloring problem of a graph, where ...
This paper considers the polyhedral results and the min–max results on packing and covering problems...
This chapter discusses polyhedral approaches in combinatorial optimization. Using a cutting-plane al...
AbstractWe present an approach based on integer programming formulations of the graph coloring probl...