The study of the graph diameter of polytopes is a classical open problem in polyhedral geometry and the theory of linear optimization. In this paper we continue the investigation initiated in [5] by introducing a vast hierarchy of generalizations to the notion of graph diameter. This hierarchy provides some interesting lower bounds for the usual graph diameter. After explaining the structure of the hierarchy and discussing these bounds, we focus on clearly explaining the differences and similarities among the many diameter notions of our hierarchy. Finally, we fully characterize the hierarchy in dimension two. It collapses into fewer categories, for which we exhibit the ranges of values that can be realized as diameters
Let ∆(d, n) be the maximum possible edge diameter over all d-dimensional polytopes defined by n ineq...
AbstractWe characterize adjacency of edge covers on the edge cover polytope of a graph G = (V, E), a...
The diameter of a set P of n points in RdRd is the maximum Euclidean distance between any two points...
The study of the graph diameter of polytopes is a classical open problem in polyhedral geometry and ...
The study of the diameter of the graph of polyhedra is a classical problem in the theory of linear p...
The combinatorial diameter of a polytope P is the maximum value of a shortest path between two verti...
Both the combinatorial and the circuit diameter of polyhedra are of interest to the theory of linear...
We study the circuit diameter of polyhedra, introduced by Borgwardt, Finhold, and Hemmecke (SIDMA 20...
We highlight intriguing analogies between the diameter of a polytope and the largest possible total ...
Abstract: "In this paper, some results on the complexity of computing the combinatorial diameter of ...
Graph associahedra are generalized permutohedra arising as special cases of nestohedra and hypergrap...
We revisit the hardness of approximating the diameter of a network. In the CONGEST model, $ \tilde \...
AbstractThe distance between two vertices of a polytope is the minimum number of edges in a path joi...
We characterize adjacency of edge covers on the edge cover polytope of a graph G = (V, E), and deriv...
The diameter of a graph is among its most basic parameters. Since a few years, it moreover became a ...
Let ∆(d, n) be the maximum possible edge diameter over all d-dimensional polytopes defined by n ineq...
AbstractWe characterize adjacency of edge covers on the edge cover polytope of a graph G = (V, E), a...
The diameter of a set P of n points in RdRd is the maximum Euclidean distance between any two points...
The study of the graph diameter of polytopes is a classical open problem in polyhedral geometry and ...
The study of the diameter of the graph of polyhedra is a classical problem in the theory of linear p...
The combinatorial diameter of a polytope P is the maximum value of a shortest path between two verti...
Both the combinatorial and the circuit diameter of polyhedra are of interest to the theory of linear...
We study the circuit diameter of polyhedra, introduced by Borgwardt, Finhold, and Hemmecke (SIDMA 20...
We highlight intriguing analogies between the diameter of a polytope and the largest possible total ...
Abstract: "In this paper, some results on the complexity of computing the combinatorial diameter of ...
Graph associahedra are generalized permutohedra arising as special cases of nestohedra and hypergrap...
We revisit the hardness of approximating the diameter of a network. In the CONGEST model, $ \tilde \...
AbstractThe distance between two vertices of a polytope is the minimum number of edges in a path joi...
We characterize adjacency of edge covers on the edge cover polytope of a graph G = (V, E), and deriv...
The diameter of a graph is among its most basic parameters. Since a few years, it moreover became a ...
Let ∆(d, n) be the maximum possible edge diameter over all d-dimensional polytopes defined by n ineq...
AbstractWe characterize adjacency of edge covers on the edge cover polytope of a graph G = (V, E), a...
The diameter of a set P of n points in RdRd is the maximum Euclidean distance between any two points...