Edge cover

In graph theory, an edge cover of a graph is a set of edges such that every vertex of the graph is incident to at least one edge of the set. In computer science, the minimum edge cover problem is the problem of finding an edge cover of minimum size. It is an optimization problem that belongs to the class of covering problems and can be solved in polynomial time.

Covering problems	Packing problems
Minimum set cover	Maximum set packing
Minimum edge cover	Maximum matching
Minimum vertex cover	Maximum independent set
Bin covering	Bin packing
Polygon covering	Rectangle packing

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Definition

Formally, an edge cover of a graph $G$ is a set of edges $C$ such that each vertex in $G$ is incident with at least one edge in $C$ . The set $C$ is said to cover the vertices of $G$ . The following figure shows examples of edge coverings in two graphs (the set $C$ is marked with red).

A minimum edge covering is an edge covering of smallest possible size. The edge covering number $ρ (G)$ is the size of a minimum edge covering. The following figure shows examples of minimum edge coverings (again, the set $C$ is marked with red).

Note that the figure on the right is not only an edge cover but also a matching. In particular, it is a perfect matching: a matching $M$ in which every vertex is incident with exactly one edge in $M$ . A perfect matching (if it exists) is always a minimum edge covering.

Examples

The set of all edges is an edge cover, assuming that there are no degree-0 vertices.
The complete bipartite graph $K m,n$ has edge covering number $max(m, n)$ .

Algorithms

A smallest edge cover can be found in polynomial time by finding a maximum matching and extending it greedily so that all vertices are covered.^[1]^[2] In the following figure, a maximum matching is marked with red; the extra edges that were added to cover unmatched nodes are marked with blue. (The figure on the right shows a graph in which a maximum matching is a perfect matching; hence it already covers all vertices and no extra edges were needed.)

On the other hand, the related problem of finding a smallest vertex cover is an NP-hard problem.^[1]

Looking at the image it already becomes obvious why, for a given minimum edge cover $C$ and maximum matching $M$ , letting $c$ and $m$ be the number of edges in $C$ and $M$ respectively, we have:^[3] $|V|=c+m$ . Indeed, $C$ contains a maximum matching, so the edges of $C$ can be decomposed between the $m$ edges of a maximum matching, covering $2m$ vertices, and the $c-m$ other edges that each cover one other vertex. Thus, as $C$ covers all of the $|V|$ vertices, we have $|V|=2m+(c-m)$ giving the desired equality.

Notes

^ ^a ^b Garey & Johnson (1979), p. 79, uses edge cover and vertex cover as one example of a pair of similar problems, one of which can be solved in polynomial time while the other one is NP-hard. See also p. 190.
^ Lawler, Eugene L. (2001), Combinatorial optimization: networks and matroids, Dover Publications, pp. 222–223, ISBN 978-0-486-41453-9.
^ "Prove that the sum of minimum edge cover and maximum matching is the vertex count". Mathematics Stack Exchange. Retrieved 2024-02-18.

References

Weisstein, Eric W. "Edge Cover". MathWorld.
Garey, Michael R.; Johnson, David S. (1979), Computers and Intractability: A Guide to the Theory of NP-Completeness, W.H. Freeman, ISBN 0-7167-1045-5.

This page was last edited on 28 February 2024, at 05:03

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