Add to ORKGIn an undirected, 2-node connected graph G = (V;E) with positive real edge lengths, the distance between any two nodes r and s is the length of a shortest path between r and s in G. The removal of a node and its incident edges from G may increase the distance from r to s. A most vital node of a given shortest path from r to s is a node (other than r and s) whose removal from G results in the largest increase of the distance from r to s. In the past, the problem of nding a most vital node of a given shortest path has been studied because of its implications in network management, where it is important to know in advance which component failure will aect network eciency the most. In this paper, we show that this problem can be solved in O(m +...
In many applications such as design of transportation networks, we often need to identify a set of r...
[[abstract]]Let G(N; A) be a connected, undirected and weighted network with node set N and edge set...
For a given graph representing a transparent optical network, a given weight associated to each node...
AbstractIn an undirected, 2-node connected graph G=(V,E) with positive real edge lengths, the distan...
We study the NP-hard Shortest Path Most Vital Edges problem arising in the context of analyzing netw...
[[abstract]]In many applications, the network designer may want to know which edges in the network a...
For a weighted, undirected graph G = (V,E), the single most vital edge in a network with respect to ...
We study the NP-hard problem of finding the most vital edges for shortest paths between two terminal...
Abstract. For a weighted, undirected graph G = (V;E) where jV j = n and jEj = m, we examine the sing...
Let G(V, E, w) be an undirected, weighted, connected simple graph. Let P be a minimization problem i...
Abstract. In transportation networks, a vehicle always travels longer than the shortest path due to ...
AbstractAssume that G(V,E) is a weighted, undirected, connected graph with n vertices. The k most vi...
Assume that G(V,E) is a weighted, undirected, connected graph with n vertices. The k most vital edge...
For a connected, undirected and weighted graph G = (V; E), the problem of finding the k most vital ...
Abstract. In this paper we consider the following problem: Given a network G, determine if there is ...
In many applications such as design of transportation networks, we often need to identify a set of r...
[[abstract]]Let G(N; A) be a connected, undirected and weighted network with node set N and edge set...
For a given graph representing a transparent optical network, a given weight associated to each node...
AbstractIn an undirected, 2-node connected graph G=(V,E) with positive real edge lengths, the distan...
We study the NP-hard Shortest Path Most Vital Edges problem arising in the context of analyzing netw...
[[abstract]]In many applications, the network designer may want to know which edges in the network a...
For a weighted, undirected graph G = (V,E), the single most vital edge in a network with respect to ...
We study the NP-hard problem of finding the most vital edges for shortest paths between two terminal...
Abstract. For a weighted, undirected graph G = (V;E) where jV j = n and jEj = m, we examine the sing...
Let G(V, E, w) be an undirected, weighted, connected simple graph. Let P be a minimization problem i...
Abstract. In transportation networks, a vehicle always travels longer than the shortest path due to ...
AbstractAssume that G(V,E) is a weighted, undirected, connected graph with n vertices. The k most vi...
Assume that G(V,E) is a weighted, undirected, connected graph with n vertices. The k most vital edge...
For a connected, undirected and weighted graph G = (V; E), the problem of finding the k most vital ...
Abstract. In this paper we consider the following problem: Given a network G, determine if there is ...
In many applications such as design of transportation networks, we often need to identify a set of r...
[[abstract]]Let G(N; A) be a connected, undirected and weighted network with node set N and edge set...
For a given graph representing a transparent optical network, a given weight associated to each node...