We study the family of problems of partitioning and covering a graph into/ with a minimum number of relaxed cliques. Relaxed cliques are subsets of vertices of a graph for which a clique-defining property—for example, the degree of the vertices, the distance between the vertices, the density of the edges, or the connectivity between the vertices—is relaxed. These graph partitioning and covering problems have important applications in many areas such as social network analysis, biology, and disease-spread prevention. We propose a unified framework based on branch-and-price techniques to compute optimal decompositions. For this purpose, new, effective pricing algorithms are developed, and new branching schemes are invented. In extensive compu...
We prove separator theorems in which the size of the separator is minimized with respect to non-nega...
Abstract. The cut packing problem in an undirected graph is to find a largest cardinality collection...
AbstractWe first consider the problem of partitioning the edges of a graph G into bipartite cliques ...
AbstractGiven a complete graph Kn=(V,E) with edge weight ce on each edge, we consider the problem of...
In this paper we discuss the problem of partitioning a permutation graph into cliques of bounded siz...
AbstractWe study the problem of clique-partitioning a graph. We prove a new general upper bound resu...
Increasing interest in studying community structures, or clusters in complex networks arising in var...
Artículo de publicación ISIWe consider the problem of partitioning a graph into cliques of bounded c...
We consider the following clustering problems: given a general undirected graph, partition its verti...
We propose a method based on combining a constructive and a bounding heuristic to solve the vertex c...
This dissertation considers graph theoretic generalizations of the maximum clique problem. Models th...
We propose a method based on combining a constructive and a bounding heuristic to solve the vertex c...
Many real-life problems can be modeled as optimization or decision problems on graphs. Also, many of...
International audienceDegree peeling is used to study complex networks. It is a decomposition of the...
Abstract We consider the problem of partitioning a graph into cliques of bounded cardinality. The go...
We prove separator theorems in which the size of the separator is minimized with respect to non-nega...
Abstract. The cut packing problem in an undirected graph is to find a largest cardinality collection...
AbstractWe first consider the problem of partitioning the edges of a graph G into bipartite cliques ...
AbstractGiven a complete graph Kn=(V,E) with edge weight ce on each edge, we consider the problem of...
In this paper we discuss the problem of partitioning a permutation graph into cliques of bounded siz...
AbstractWe study the problem of clique-partitioning a graph. We prove a new general upper bound resu...
Increasing interest in studying community structures, or clusters in complex networks arising in var...
Artículo de publicación ISIWe consider the problem of partitioning a graph into cliques of bounded c...
We consider the following clustering problems: given a general undirected graph, partition its verti...
We propose a method based on combining a constructive and a bounding heuristic to solve the vertex c...
This dissertation considers graph theoretic generalizations of the maximum clique problem. Models th...
We propose a method based on combining a constructive and a bounding heuristic to solve the vertex c...
Many real-life problems can be modeled as optimization or decision problems on graphs. Also, many of...
International audienceDegree peeling is used to study complex networks. It is a decomposition of the...
Abstract We consider the problem of partitioning a graph into cliques of bounded cardinality. The go...
We prove separator theorems in which the size of the separator is minimized with respect to non-nega...
Abstract. The cut packing problem in an undirected graph is to find a largest cardinality collection...
AbstractWe first consider the problem of partitioning the edges of a graph G into bipartite cliques ...