Triangle graph: Difference between revisions

Revision as of 03:45, 29 May 2012

This article defines a particular undirected graph, i.e., the definition here determines the graph uniquely up to graph isomorphism.
View a complete list of particular undirected graphs

Definition

This is a particular finite undirected graph defined as follows:

It is a graph whose geometric realization is a triangle: it has three vertices and an edge between each pair of vertices.
It is the cycle graph on 3 vertices, and is denoted $C_{3}$ .
It is the complete graph on 3 vertices, and is denoted $K_{3}$ .
It is the odd graph $O_{2}$ , i.e., the Kneser graph $KG_{3,1}$ .

Arithmetic functions

Size measures

Function	Value	Explanation
size of vertex set	3	As $C_{n},n=3$ : $n=3$ As $K_{n},n=3$ : $n=3$ As $O_{n},n=2$ : ${\binom {2n-1}{n-1}}={\binom {3}{1}}=3$
size of edge set	3	As $C_{n},n=3$ : $n=3$ As $K_{n},n=3$ : ${\binom {n}{2}}={\binom {3}{2}}=3$ As $O_{n},n=2$ : ${\binom {2n-1}{n-1,n-1,1}}={\binom {3}{1,1,1}}=3$

Numerical invariants associated with vertices

Since the graph is a vertex-transitive graph, any numerical invariant associated to a vertex must be equal on all vertices of the graph. Below are listed some of these invariants:

Function	Value	Explanation
degree of a vertex	2	As $C_{n},n=3$ : 2 (independent of $n$ ) As $K_{n},n=3$ : $n-1=2$ As $O_{n},n=2$ : $n=2$
eccentricity of a vertex	1	As $C_{n},n=3$ : greatest integer function of $n/2$ equals greatest integer function of 3/2 equals 1 As $K_{n},n=3$ : 1 (true for any $n\geq 2$ ) As $O_{n},n=2$ : $n-1=1$

Other numerical invariants

Function	Value	Explanation
clique number	3	As $C_{n},n=3$ : 3 (since $n=3$ ; it's 2 for larger $n$ ) As $K_{n},n=3$ : $n=3$ As $O_{n},n=2$ : 3
independence number	1	As $C_{n},n=3$ : greatest integer function of $n/2$ equals greatest integer function of 3/2 equals 1 As $K_{n},n=3$ : 1 (independent of $n$ )
chromatic number	3	As $C_{n},n=3$ : 3 since $n$ is odd As $K_{n},n=3$ : $n=3$
radius of a graph	1	Due to vertex-transitivity, the radius equals the eccentricity of any vertex, which has been computed above.
diameter of a graph	1	Due to vertex-transitivity, the radius equals the eccentricity of any vertex, which has been computed above.
odd girth	3	As $C_{n},n=3$ : $n=3$ As $K_{n},n=3$ : 3 (true for any $n\geq 3$ ) As $O_{n},n=2$ : $2n-1=2(2)-1=3$
even girth	infinite	there are no cycles of even length
girth of a graph	3	minimum of even and odd girth

@@ Line 9: / Line 9: @@
 # It is the [[complete graph]] on 3 vertices, and is denoted <math>K_3</math>.
 # It is the [[odd graph]] <math>O_2</math>, i.e., the [[Kneser graph]] <math>KG_{3,1}</math>.
+==Arithmetic functions==
+===Size measures===
+{| class="sortable" border="1"
+! Function !! Value !! Explanation
+|-
+| {{arithmetic function value|size of vertex set|3}} || As <math>C_n, n =3 </math>: <matH>n = 3</math><br>As <math>K_n , n = 3</math>: <math>n= 3</math><br>As <math>O_n, n= 2</math>: <math>\binom{2n - 1}{n - 1} = \binom{3}{1} = 3</math>
+|-
+| {{arithmetic function value|size of edge set|3}} || As <math>C_n, n =3 </math>: <matH>n = 3</math><br>As <math>K_n , n = 3</math>: <math>\binom{n}{2}= \binom{3}{2} = 3</math><br>As <math>O_n, n= 2</math>: <math>\binom{2n - 1}{n - 1,n-1,1} = \binom{3}{1,1,1} = 3</math>
+|}
+===Numerical invariants associated with vertices===
+Since the graph is a [[vertex-transitive graph]], any numerical invariant associated to a vertex must be equal on all vertices of the graph. Below are listed some of these invariants:
+{| class="sortable" border="1"
+! Function !! Value !! Explanation
+|-
+| {{arithmetic function value|degree of a vertex|2}} || As <math>C_n, n = 3</math>: 2 (independent of <math>n</math>)<br>As <math>K_n, n = 3</math>: <math>n - 1 = 2</math><br>As <math>O_n, n = 2</math>: <math>n = 2</math>
+|-
+| {{arithmetic function value|eccentricity of a vertex|1}} || As <math>C_n, n = 3</math>: greatest integer function of <math>n/2</math> equals greatest integer function of 3/2 equals 1<br>As <math>K_n, n = 3</math>: 1 (true for any <math>n \ge 2</math>)<br>As <math>O_n, n= 2</math>: <math>n - 1 = 1</math>
+|}
+===Other numerical invariants===
+{| class="sortable" border="1"
+! Function !! Value !! Explanation
+|-
+| {{arithmetic function value|clique number|3}} || As <math>C_n, n = 3</math>: 3 (since <math>n = 3</math>; it's 2 for larger <math>n</math>)<br>As <math>K_n, n = 3</math>: <math>n= 3</math><br>As <math>O_n, n = 2</math>: 3
+|-
+| {{arithmetic function value|independence number|1}} || As <math>C_n, n = 3</math>: greatest integer function of <math>n/2</math> equals greatest integer function of 3/2 equals 1<br>As <math>K_n, n = 3</math>: 1 (independent of <matH>n</math>)
+|-
+| {{arithmetic function value|chromatic number|3}} || As <math>C_n, n = 3</math>: 3 since <matH>n</math> is odd<br>As <math>K_n, n= 3</math>: <math>n = 3</math>
+|-
+| {{arithmetic function value|radius of a graph|1}} || Due to vertex-transitivity, the radius equals the eccentricity of any vertex, which has been computed above.
+|-
+| {{arithmetic function value|diameter of a graph|1}} || Due to vertex-transitivity, the radius equals the eccentricity of any vertex, which has been computed above.
+|-
+| {{arithmetic function value|odd girth|3}} || As <math>C_n, n = 3</math>: <matH>n = 3</math><br>As <math>K_n, n = 3</math>: 3 (true for any <math>n \ge 3</math>)<br>As <math>O_n, n = 2</math>: <math>2n - 1 = 2(2) - 1 = 3</math>
+|-
+| [[even girth]] || infinite || there are no cycles of even length
+|-
+| {{arithmetic function value|girth of a graph|3}} || minimum of even and odd girth
+|}