Vertex separator

In graph theory, a vertex subset $S\subset V$ is a vertex separator (or vertex cut, separating set) for nonadjacent vertices $a$ and $b$ if the removal of $S$ from the graph separates $a$ and $b$ into distinct connected components.

Examples[edit]

Consider a grid graph with $r$ rows and $c$ columns; the total number $n$ of vertices is $r \times c$ . For instance, in the illustration, $r = 5$ , $c = 8$ , and $n = 40$ . If $r$ is odd, there is a single central row, and otherwise there are two rows equally close to the center; similarly, if $c$ is odd, there is a single central column, and otherwise there are two columns equally close to the center. Choosing $S$ to be any of these central rows or columns, and removing $S$ from the graph, partitions the graph into two smaller connected subgraphs $A$ and $B$ , each of which has at most $.mw-parser-output .frac{white-space:nowrap}.mw-parser-output .frac .num,.mw-parser-output .frac .den{font-size:80%;line-height:0;vertical-align:super}.mw-parser-output .frac .den{vertical-align:sub}.mw-parser-output .sr-only{border:0;clip:rect(0,0,0,0);clip-path:polygon(0px 0px,0px 0px,0px 0px);height:1px;margin:-1px;overflow:hidden;padding:0;position:absolute;width:1px}n⁄2$ vertices. If $r \leq c$ (as in the illustration), then choosing a central column will give a separator $S$ with $r\leq {\sqrt {n}}$ vertices, and similarly if $c \leq r$ then choosing a central row will give a separator with at most ${\sqrt {n}}$ vertices. Thus, every grid graph has a separator $S$ of size at most ${\sqrt {n}},$ the removal of which partitions it into two connected components, each of size at most $n ⁄ 2$ .^[1]

On the left a centered tree, on the right a bicentered one. The numbers show each node's eccentricity.

To give another class of examples, every free tree $T$ has a separator $S$ consisting of a single vertex, the removal of which partitions $T$ into two or more connected components, each of size at most $n ⁄ 2$ . More precisely, there is always exactly one or exactly two vertices, which amount to such a separator, depending on whether the tree is centered or bicentered.^[2]

As opposed to these examples, not all vertex separators are balanced, but that property is most useful for applications in computer science, such as the planar separator theorem.

Minimal separators[edit]

Let $S$ be an $(a, b)$ -separator, that is, a vertex subset that separates two nonadjacent vertices $a$ and $b$ . Then $S$ is a minimal $(a, b)$ -separator if no proper subset of $S$ separates $a$ and $b$ . More generally, $S$ is called a minimal separator if it is a minimal separator for some pair $(a, b)$ of nonadjacent vertices. Notice that this is different from minimal separating set which says that no proper subset of $S$ is a minimal $(u, v)$ -separator for any pair of vertices $(u, v)$ . The following is a well-known result characterizing the minimal separators:^[3]

Lemma. A vertex separator $S$ in $G$ is minimal if and only if the graph $G - S$ , obtained by removing $S$ from $G$ , has two connected components $C 1$ and $C 2$ such that each vertex in $S$ is both adjacent to some vertex in $C 1$ and to some vertex in $C 2$ .

The minimal $(a, b)$ -separators also form an algebraic structure: For two fixed vertices $a$ and $b$ of a given graph $G$ , an $(a, b)$ -separator $S$ can be regarded as a predecessor of another $(a, b)$ -separator $T$ , if every path from $a$ to $b$ meets $S$ before it meets $T$ . More rigorously, the predecessor relation is defined as follows: Let $S$ and $T$ be two $(a, b)$ -separators in $G$ . Then $S$ is a predecessor of $T$ , in symbols $S\sqsubseteq _{a,b}^{G}T$ , if for each $x ∈ S \ T$ , every path connecting $x$ to $b$ meets $T$ . It follows from the definition that the predecessor relation yields a preorder on the set of all $(a, b)$ -separators. Furthermore, Escalante (1972) proved that the predecessor relation gives rise to a complete lattice when restricted to the set of minimal $(a, b)$ -separators in $G$ .

Notes[edit]

^ George (1973). Instead of using a row or column of a grid graph, George partitions the graph into four pieces by using the union of a row and a column as a separator.
^ Jordan (1869)
^ Golumbic (1980).

References[edit]

Escalante, F. (1972). "Schnittverbände in Graphen". Abhandlungen aus dem Mathematischen Seminar der Universität Hamburg. 38: 199–220. doi:10.1007/BF02996932.
George, J. Alan (1973), "Nested dissection of a regular finite element mesh", SIAM Journal on Numerical Analysis, 10 (2): 345–363, doi:10.1137/0710032, JSTOR 2156361.
Golumbic, Martin Charles (1980), Algorithmic Graph Theory and Perfect Graphs, Academic Press, ISBN 0-12-289260-7.
Jordan, Camille (1869). "Sur les assemblages de lignes". Journal für die reine und angewandte Mathematik (in French). 70 (2): 185–190.
Rosenberg, Arnold; Heath, Lenwood (2002). Graph Separators, with Applications. Springer. doi:10.1007/b115747.

[g73-1] George (1973). Instead of using a row or column of a grid graph, George partitions the graph into four pieces by using the union of a row and a column as a separator.

[Jordan-2] Jordan (1869)

[3] Golumbic (1980).

[1]

[2]

[3]

Examples[edit]

Minimal separators[edit]

See also[edit]

Notes[edit]

References[edit]