Given a finite, simple graph $G$, the $k$-component order edge connectivity of $G$ is the minimum number of edges whose removal results in a subgraph for which every component has order at most $k-1$. In general, determining the $k$-component order edge connectivity of a graph is NP-hard. We determine conditions on the vertex degrees of $G$ that can be used to imply a lower bound on the $k$-component order edge connectivity of $G$. We will discuss the process for generating such conditions for a lower bound of 1 or 2, and we explore how the complexity increases when the desired lower bound is 3 or more. In the process, we prove some related results about integer partitions
International audienceThe k-restricted edge-connectivity of a graph G, denoted by λ k (G), is define...
For every integer k ≥ 2 and graph G, consider the following natural procedure: if G has a component ...
AbstractLet G be a λk-connected graph. G is called λk-optimal, if its k-restricted edge-connectivity...
AbstractIt was proved by Chartrand that if G is a graph of order p for which the minimum degree is a...
AbstractThe note contains some conditions on a graph implying that the edge connectivity is equal to...
Let G be a connected graph with p ≥ 2 vertices. For k = 1, 2, ..., P-1, the Kth order edge-connectiv...
AbstractWe characterize graphs of large enough order or large enough minimum degree which contain ed...
We characterize graphs of large enough order or large enough minimum degree which contain edge cuts ...
AbstractThis work deals with a generalization of the Cartesian product of graphs, the product graph ...
AbstractFor every integer k⩾2 and graph G, consider the following natural procedure: if G has a comp...
AbstractFor a connected graph G, the restricted edge-connectivity λp(G) is defined as the minimum ca...
AbstractFor a connected graph G, an edge set S is a k-restricted edge-cut if G−S is disconnected and...
AbstractFor an undirected multigraph G=(V,E), let α be a positive integer weight function on V. For ...
International audienceA circuit in a simple undirected graph G=(V,E) is a sequence of vertices {v_1,...
AbstractIt is shown that if G is a graph of order p ≥ 2 such that deg u + deg v ≥ p − 1 for all pair...
International audienceThe k-restricted edge-connectivity of a graph G, denoted by λ k (G), is define...
For every integer k ≥ 2 and graph G, consider the following natural procedure: if G has a component ...
AbstractLet G be a λk-connected graph. G is called λk-optimal, if its k-restricted edge-connectivity...
AbstractIt was proved by Chartrand that if G is a graph of order p for which the minimum degree is a...
AbstractThe note contains some conditions on a graph implying that the edge connectivity is equal to...
Let G be a connected graph with p ≥ 2 vertices. For k = 1, 2, ..., P-1, the Kth order edge-connectiv...
AbstractWe characterize graphs of large enough order or large enough minimum degree which contain ed...
We characterize graphs of large enough order or large enough minimum degree which contain edge cuts ...
AbstractThis work deals with a generalization of the Cartesian product of graphs, the product graph ...
AbstractFor every integer k⩾2 and graph G, consider the following natural procedure: if G has a comp...
AbstractFor a connected graph G, the restricted edge-connectivity λp(G) is defined as the minimum ca...
AbstractFor a connected graph G, an edge set S is a k-restricted edge-cut if G−S is disconnected and...
AbstractFor an undirected multigraph G=(V,E), let α be a positive integer weight function on V. For ...
International audienceA circuit in a simple undirected graph G=(V,E) is a sequence of vertices {v_1,...
AbstractIt is shown that if G is a graph of order p ≥ 2 such that deg u + deg v ≥ p − 1 for all pair...
International audienceThe k-restricted edge-connectivity of a graph G, denoted by λ k (G), is define...
For every integer k ≥ 2 and graph G, consider the following natural procedure: if G has a component ...
AbstractLet G be a λk-connected graph. G is called λk-optimal, if its k-restricted edge-connectivity...