Theorem

Define Order of an Element g of Finite Group G:

o(g) = the least positive integer n such that gⁿ = e

Define Order of a Cyclic Subgroup generated by g:

o(\langle g\rangle )

= # elements in

\langle g\rangle

o(g) =

o(\langle g\rangle )

Proof

By diagram,

0.

g^{o(\langle g\rangle )}=e=g^{o(g)}

.

1. Let n = o(g), and m =

o(\langle g\rangle )

2. gⁿ = g^m

3. g^{n – m} = e

4. Let n – m = sn + r where r, n, s are integers and 0 ≤ s < n.

5. g^{sn + r} = e

6.

[g^{n}]^{s}\ast g^{r}=e

By definition of n = o(g)

7. g^r = e

As n is the least that makes gⁿ = e and 0 ≤ r < n.

8. r = 0

Lemma: Let $k,m\in \mathbb {Z}$ .
$g^{k}=g^{m}$ if and only if $k\equiv m(\,{\bmod {\ }}o(g))$ .
Proof: Let $n=o(g)$ .
$g^{k}=g^{m}$ if and only if $g^{k-m}=e$ .
By Euclidean division: $k-m=qn+r$ , some integers $q,r$ with $0\leq r<n$ .
We have $g^{r}=g^{k-m-qn}=g^{k-m}{(g^{n})}^{-q}=g^{k-m}$ , hence $g^{r}=e$ if and only if $g^{k}=g^{m}$ .
But $g^{r}=e$ if and only if $r=0$ (i.e. if and only if $n\mid k-n$ ),
since, by definition, $n=o(g)$ is the least positive integer satisfying $g^{n}=e$ .
Hence the result. $\square$

By definition: $\langle g\rangle =\{g^{r}:r\in \mathbb {Z} \}$ .
Therefore, $g,g^{2},\ldots ,g^{n}$ (where $n=o(g)$ ) all lie in $\langle g\rangle$ – furthermore, by lemma above, these are pairwise distinct.
Finally, any element of the form $g^{r}$ , $r\in \mathbb {Z}$ equals one of $g,g^{2},\ldots ,g^{n}$ (again by lemma).
We conclude that $g,g^{2},\ldots ,g^{n}$ are precisely the elements of $\langle g\rangle$ ,
so $o(\langle g\rangle )=n=o(g)$ , as required.
- Q.E.D. -