We provide upper bounds for the determining number and the metric dimension of tournaments. A set of vertices S in V(T) is a determining set for a tournament T if every nontrivial automorphism of T moves at least one vertex of S, while S is a resolving set for T if every two distinct vertices in T have different distances to some vertex in S. We show that the minimum size of a determining set for an order n tournament (its determining number) is bounded by n/3, while the minimum size of a resolving set for an order n strong tournament (its metric dimension) is bounded by n/2. Both bounds are optimal.Peer Reviewe
We present new bounds on the locality of several classical symmetry breaking tasks in dis-tributed n...
We study combinatorial and algorithmic questions around minimal feedback vertex sets (fvs) in tourna...
This paper examines the problem of rank ordering a set of players or objects on the basis of a set o...
We provide upper bounds for the determining number and the metric dimension of tournaments. A set of...
This paper deals with the maximum value of the difference between the determining number and the me...
6ppInternational audienceWe consider the transformation reversing all arcs of a subset $X$ of the ve...
A knockout (or single-elimination) tournament is a format of a competition that is very popular in p...
Determining vertex subsets are known tools to provide information about automorphism groups of graph...
In a strongly connected digraph, we consider the problem of finding a set of minimum size that is bo...
We define and study the graph-theoretic notion of an anchor in a tournament. An anchor in a tourname...
A tournament solution is a function that maps a tournament, i.e., a directed graph representing an a...
A tournament T = (X; E) is a complete oriented asymmetric graph: between two vertices x and y with x...
We study feedback vertex sets (FVS) in tournaments, which are orientations of complete graphs. As ou...
A resolving set is a set W of vertices of a connected graph G(V, E) such that for every pair of vert...
We study the maximum value of the difference between the metric dimension and the determining number...
We present new bounds on the locality of several classical symmetry breaking tasks in dis-tributed n...
We study combinatorial and algorithmic questions around minimal feedback vertex sets (fvs) in tourna...
This paper examines the problem of rank ordering a set of players or objects on the basis of a set o...
We provide upper bounds for the determining number and the metric dimension of tournaments. A set of...
This paper deals with the maximum value of the difference between the determining number and the me...
6ppInternational audienceWe consider the transformation reversing all arcs of a subset $X$ of the ve...
A knockout (or single-elimination) tournament is a format of a competition that is very popular in p...
Determining vertex subsets are known tools to provide information about automorphism groups of graph...
In a strongly connected digraph, we consider the problem of finding a set of minimum size that is bo...
We define and study the graph-theoretic notion of an anchor in a tournament. An anchor in a tourname...
A tournament solution is a function that maps a tournament, i.e., a directed graph representing an a...
A tournament T = (X; E) is a complete oriented asymmetric graph: between two vertices x and y with x...
We study feedback vertex sets (FVS) in tournaments, which are orientations of complete graphs. As ou...
A resolving set is a set W of vertices of a connected graph G(V, E) such that for every pair of vert...
We study the maximum value of the difference between the metric dimension and the determining number...
We present new bounds on the locality of several classical symmetry breaking tasks in dis-tributed n...
We study combinatorial and algorithmic questions around minimal feedback vertex sets (fvs) in tourna...
This paper examines the problem of rank ordering a set of players or objects on the basis of a set o...