Difference between revisions of "Factorization"
From Encyclopedia of Mathematics
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''in graph theory'' | ''in graph theory'' | ||
| − | The decomposition of a [[Graph|graph]] into edge-disjoint spanning subgraphs of a special form. In the general case a factor is a spanning subgraph with a given property. An example of such a property is regularity. A regular spanning subgraph of degree | + | The decomposition of a [[Graph|graph]] into edge-disjoint spanning subgraphs of a special form. In the general case a factor is a spanning subgraph with a given property. An example of such a property is regularity. A regular spanning subgraph of degree is called a k-factor; a 1-factor is also called a perfect matching. A graph is called k-factorizable (or k-factorable) if it can be represented as a union of edge-disjoint k-factors. |
| − | In graph theory one considers questions on the existence of factors of one type or another in an arbitrary graph, on the number of factors, and on the possibility of a factorization of a given type for different classes of graphs. It is known, for example, that a complete graph with an even number of vertices and a complete bipartite graph (cf. [[Graph, bipartite|Graph, bipartite]]) with the same number of vertices in each part are | + | In graph theory one considers questions on the existence of factors of one type or another in an arbitrary graph, on the number of factors, and on the possibility of a factorization of a given type for different classes of graphs. It is known, for example, that a complete graph with an even number of vertices and a complete bipartite graph (cf. [[Graph, bipartite|Graph, bipartite]]) with the same number of vertices in each part are 1-factorizable. A connected graph is 2-factorizable if and only if it is a regular graph of even degree. A graph G has a 1-factor if and only if it has an even number of vertices and if there is no subset of vertices U such that the number of components with an odd number of vertices of the graph G\setminus U, obtained from G by deleting the vertices of U, exceeds |U|. Every two-connected regular graph of degree 3 can be decomposed into a 1-factor and a 2-factor which are edge-disjoint. |
| − | Examples of non-regular factors are spanning trees (cf. [[Tree|Tree]]) and forests, spanning planar subgraphs (see [[Graph imbedding|Graph imbedding]]), etc. Connected with the decomposition of a graph into spanning forests is the numerical characteristic called the arboricity; this is the least number of edge-disjoint spanning forests whose union is the graph. The arboricity of an arbitrary graph | + | Examples of non-regular factors are spanning trees (cf. [[Tree|Tree]]) and forests, spanning planar subgraphs (see [[Graph imbedding|Graph imbedding]]), etc. Connected with the decomposition of a graph into spanning forests is the numerical characteristic called the arboricity; this is the least number of edge-disjoint spanning forests whose union is the graph. The arboricity of an arbitrary graph G is equal to |
| − | + | $$\max_k=\{\frac{g_k}{k-1}\},$$ | |
| − | where | + | where g_k is the largest number of edges in the k-vertex subgraphs of G. |
====References==== | ====References==== | ||
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====Comments==== | ====Comments==== | ||
| − | A spanning subgraph of a graph | + | A spanning subgraph of a graph $G=(V,E)$ is a subgraph $G_1=(V_1,E_1)$ whose set of vertices V_1 is equal to the set of vertices V of G. |
| − | The | + | The 1-factor theorem quoted above is due to W.T. Tutte. Given a vertex function $f$, a factor F is called an $f$-factor if $d(v|F)=f(x)$ for every v\in V, the vertex set of G. Tutte also proved an $f$-factor theorem. The results on 2-factors mentioned above are due to J. Petersen [[#References|[a1]]]. A comprehensive treatment of all these results is given by Tutte in [[#References|[a2]]]. A recent survey is [[#References|[a3]]]. |
====References==== | ====References==== | ||
<table><TR><TD valign="top">[a1]</TD> <TD valign="top"> J. Petersen, "Die theorie der regulären Graphen" ''Acta. Math.'' , '''15''' (1891) pp. 193–220</TD></TR><TR><TD valign="top">[a2]</TD> <TD valign="top"> W.T. Tutte, "Graph factors" ''Combinatorica'' , '''1''' (1981) pp. 79–97</TD></TR><TR><TD valign="top">[a3]</TD> <TD valign="top"> J. Akiyama, M. Kano, "Factors and factorizations of graphs - a survey" ''J. Graph Theory'' , '''9''' (1985) pp. 1–42</TD></TR></table> | <table><TR><TD valign="top">[a1]</TD> <TD valign="top"> J. Petersen, "Die theorie der regulären Graphen" ''Acta. Math.'' , '''15''' (1891) pp. 193–220</TD></TR><TR><TD valign="top">[a2]</TD> <TD valign="top"> W.T. Tutte, "Graph factors" ''Combinatorica'' , '''1''' (1981) pp. 79–97</TD></TR><TR><TD valign="top">[a3]</TD> <TD valign="top"> J. Akiyama, M. Kano, "Factors and factorizations of graphs - a survey" ''J. Graph Theory'' , '''9''' (1985) pp. 1–42</TD></TR></table> | ||
Revision as of 14:40, 17 July 2014
in graph theory
The decomposition of a graph into edge-disjoint spanning subgraphs of a special form. In the general case a factor is a spanning subgraph with a given property. An example of such a property is regularity. A regular spanning subgraph of degree k is called a k-factor; a 1-factor is also called a perfect matching. A graph is called k-factorizable (or k-factorable) if it can be represented as a union of edge-disjoint k-factors.
In graph theory one considers questions on the existence of factors of one type or another in an arbitrary graph, on the number of factors, and on the possibility of a factorization of a given type for different classes of graphs. It is known, for example, that a complete graph with an even number of vertices and a complete bipartite graph (cf. Graph, bipartite) with the same number of vertices in each part are 1-factorizable. A connected graph is 2-factorizable if and only if it is a regular graph of even degree. A graph G has a 1-factor if and only if it has an even number of vertices and if there is no subset of vertices U such that the number of components with an odd number of vertices of the graph G\setminus U, obtained from G by deleting the vertices of U, exceeds |U|. Every two-connected regular graph of degree 3 can be decomposed into a 1-factor and a 2-factor which are edge-disjoint.
Examples of non-regular factors are spanning trees (cf. Tree) and forests, spanning planar subgraphs (see Graph imbedding), etc. Connected with the decomposition of a graph into spanning forests is the numerical characteristic called the arboricity; this is the least number of edge-disjoint spanning forests whose union is the graph. The arboricity of an arbitrary graph G is equal to
\max_k=\{\frac{g_k}{k-1}\},
where g_k is the largest number of edges in the k-vertex subgraphs of G.
References
| [1] | F. Harary, "Graph theory" , Addison-Wesley (1969) pp. Chapt. 9 |
Comments
A spanning subgraph of a graph G=(V,E) is a subgraph G_1=(V_1,E_1) whose set of vertices V_1 is equal to the set of vertices V of G.
The 1-factor theorem quoted above is due to W.T. Tutte. Given a vertex function f, a factor F is called an f-factor if d(v|F)=f(x) for every v\in V, the vertex set of G. Tutte also proved an f-factor theorem. The results on 2-factors mentioned above are due to J. Petersen [a1]. A comprehensive treatment of all these results is given by Tutte in [a2]. A recent survey is [a3].
References
| [a1] | J. Petersen, "Die theorie der regulären Graphen" Acta. Math. , 15 (1891) pp. 193–220 |
| [a2] | W.T. Tutte, "Graph factors" Combinatorica , 1 (1981) pp. 79–97 |
| [a3] | J. Akiyama, M. Kano, "Factors and factorizations of graphs - a survey" J. Graph Theory , 9 (1985) pp. 1–42 |
How to Cite This Entry:
Factorization. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Factorization&oldid=14321
Factorization. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Factorization&oldid=14321
This article was adapted from an original article by A.A. Sapozhenko (originator), which appeared in Encyclopedia of Mathematics - ISBN 1402006098. See original article