AbstractA graph is k-ordered if, for any sequence of k vertices, there is a cycle containing these vertices in the given order. A graph is k-edge-ordered if, for any sequence of k edges, there is a tour containing these edges in the given order. Finally, a graph is strongly k-edge-ordered if for any sequence of k oriented edges, there is a tour containing these edges in the given order and in the given orientations. In this paper, we prove that every 2k-ordered (resp. (2k+1)-ordered) graph is k-edge-ordered (resp. strongly k-edge-ordered). We also examine degree conditions and connectivity for k-edge-ordered graphs, and state results on k-edge-ordered Eulerian graphs
International audienceA circuit in a simple undirected graph G=(V,E) is a sequence of vertices {v_1,...
Canonical orderings and their relatives such as st-numberings have been used as a key tool in algori...
AbstractWe prove (i) if G is a 2k-edge-connected graph (k≥2), s, t are vertices, and f1, f2, g are e...
AbstractA graph is k-ordered if, for any sequence of k vertices, there is a cycle containing these v...
A graph G is called k-ordered if for every sequence of k distinct vertices there is a cycle traversi...
AbstractA simple graph G is k-ordered (respectively, k-ordered hamiltonian) if, for any sequence of ...
AbstractA graph G is called k-ordered if for any sequence of k distinct vertices of G, there exists ...
AbstractFor a positive integer k, a graph G is k-ordered if for every ordered set of k vertices, the...
AbstractFor a positive integer k, a graph G is k-ordered if for every ordered sequence of k vertices...
In 1997, Ng and Schultz introduced the idea of cycle orderability. For a positive integer k, a graph...
AbstractIt is known that if G is a connected simple graph, then G3 is Hamiltonian (in fact, Hamilton...
Given a finite, simple graph $G$, the $k$-component order edge connectivity of $G$ is the minimum nu...
AbstractA graph G of order n is k-ordered hamiltonian, 2≤k≤n, if for every sequence v1,v2,…,vk of k ...
Over the years Hamiltonian graphs have been widely studied. Various Hamiltonian-related properties h...
Canonical orderings and their relatives such as st-numberings have been used as a key tool in algori...
International audienceA circuit in a simple undirected graph G=(V,E) is a sequence of vertices {v_1,...
Canonical orderings and their relatives such as st-numberings have been used as a key tool in algori...
AbstractWe prove (i) if G is a 2k-edge-connected graph (k≥2), s, t are vertices, and f1, f2, g are e...
AbstractA graph is k-ordered if, for any sequence of k vertices, there is a cycle containing these v...
A graph G is called k-ordered if for every sequence of k distinct vertices there is a cycle traversi...
AbstractA simple graph G is k-ordered (respectively, k-ordered hamiltonian) if, for any sequence of ...
AbstractA graph G is called k-ordered if for any sequence of k distinct vertices of G, there exists ...
AbstractFor a positive integer k, a graph G is k-ordered if for every ordered set of k vertices, the...
AbstractFor a positive integer k, a graph G is k-ordered if for every ordered sequence of k vertices...
In 1997, Ng and Schultz introduced the idea of cycle orderability. For a positive integer k, a graph...
AbstractIt is known that if G is a connected simple graph, then G3 is Hamiltonian (in fact, Hamilton...
Given a finite, simple graph $G$, the $k$-component order edge connectivity of $G$ is the minimum nu...
AbstractA graph G of order n is k-ordered hamiltonian, 2≤k≤n, if for every sequence v1,v2,…,vk of k ...
Over the years Hamiltonian graphs have been widely studied. Various Hamiltonian-related properties h...
Canonical orderings and their relatives such as st-numberings have been used as a key tool in algori...
International audienceA circuit in a simple undirected graph G=(V,E) is a sequence of vertices {v_1,...
Canonical orderings and their relatives such as st-numberings have been used as a key tool in algori...
AbstractWe prove (i) if G is a 2k-edge-connected graph (k≥2), s, t are vertices, and f1, f2, g are e...