User:Abelvikram/sandbox

=Introduction= In mathematics, particularly in combinatorial group theory, a normal form for a free group over a set of generators or for a free product of groups is a representation of an element by a simpler element, the element being either in the free group or free products of group. In case of free group these simpler elements are reduced words and in the case of free product of groups these are reduced sequences. The precise definitions of these are given below. As it turns out, for a free group and for the free product of groups, there exists a unique normal form i.e each element is representable by a simpler element and this representation is unique. This is the Normal Form Theorem for the free groups and for the free product of groups. The proof here of the Normal Form Theorem follows the idea of Artin and van der Waerden.

Normal form for free groups
Let $$G$$ be a free group with generating set $$S$$. Each element in $$G$$ is represented by a word $$w$$, $$w=a_1a_2\ldots\,a_n$$, where $$a_j\in\,S^{\pm}\,\forall\,1\leq\,j\leq\,n.$$

Definition(Reduced Word)
A word $$w$$ is reduced if it contains no part $$aa^{-1},\,a\in\,S^{\pm}$$.

Definition(Normal Form)
A normal form for a free group $$G$$ with generating set $$S$$ is a choice of a reduced word in $$S$$ for each element of $$G$$.

Normal Form Theorem for free groups
Statement A free group has a unique normal form i.e. each element in $$G$$ is represented by a unique reduced word.

Proof An elementary transformation of a word $$w\in\,G$$ consists of inserting or deleting a part of the form $$aa^{-1}\,a\in\,S^{\pm}$$. Two words $$w_1$$ and $$w_2$$ are equivalent, $$w_1\equiv\,w_2$$, if there is a chain of elementary transformations leading from $$w_1$$ to $$w_2$$. This is obviously an equivalence relation on $$G$$. Let $$G_0$$ be the set of reduced words. We shall show that each equivalence class of words contains exactly one reduced word. It is clear that each equivalence class contains a reduced word, since successive deletion of parts $$aa^{-1}$$ from any word $$w$$ must lead to a reduced word. It will suffice then to show that distinct reduced words $$u$$ and $$v$$ are not equivalent. For each $$x\in\,S$$ define a permutation $$x\Delta$$ of $$G_0$$ by setting $$w(x\Delta)=wx$$ if $$wx$$ is reduced and $$w(x\Delta)=u$$ if $$w=ux^{-1}$$. Let $$P$$ be the group of permutations of $$G_0$$ generated by the $$x\Delta,\,x\in\,S$$. Let $${\Delta}^{*}$$ be the multiplicative extension of $$\Delta$$ to a map $${\Delta}^{*}:W\mapsto\,P$$. If $$u_1\equiv\,u_2,$$ then $$u_1{\Delta}^{*}=u_2{\Delta}^{*}$$; moreover $$1(u{\Delta}^{*})=u_0$$ is reduced with $$u_0\equiv\,u.$$ It follows that if $$u_1\equiv\,u_2$$ with $$u_1,\,u_2$$ reduced, then $$u_1=u_2$$.



Normal form for free products
Let $$G\,=\,A\,*\,B$$ be the free product of groups $$A$$ and $$B$$. Every element $$w\,\in\,G$$ is represented by $$w\,=\,g_1g_2...g_n$$ where $$g_j\in\,A\,\,\text{or}\,\,B$$ for $$1\leq\,j\leq\,n$$.

Definition(Reduced Sequence)
A reduced sequence is a sequence $$g_1,\,g_2\ldots\,g_n$$ such that $$g_j\,\in\,A\,\text{or}\,B\,\forall\,1\leq\,j\leq\,n$$ with the property that $$g_j\,\neq\,e\,\forall\,j,$$ and $$g_j,\,g_{j+1}$$ are not in the same factor $$A$$ or $$B$$.

Definition(Normal Form)
A normal form for a free product of groups is a representation or choice of a reduced sequence for each element in the free product.

Normal Form Theorem for free product of groups
There are two equivalent version of Normal Form Theorem in the case of Free products.

Statement Consider the free product $$A*B$$ of two groups $$A$$ and $$B$$. Then the following two equivalent statements hold.


 * If $$w=g_1g_2\cdots g_n \,\, ,n>0$$, where $$g_1,g_2,\dots, g_n$$ is a reduced sequence, then $$w\neq 1$$ in $$A*B$$.
 * Each element $$w$$ of $$A*B$$ can be written uniquely as $$w=g_1g_2\cdots g_n$$ where $$g_1,g_2,\dots ,g_n$$ is a reduced sequence (for $$w=1$$ we will take the reduced sequence to be empty).

Proof : First consider the equivalence of the above two statements.

The second statement implies the first is easy.

Suppose the first statement holds. Let $$w=g_1 g_2\cdots g_m$$ and $$w=h_1 h_2\cdots h_n$$, then we have $$g_1 g_2\cdots g_m\,=\,h_1 h_2\cdots h_n.$$, which implies $$h_n^{-1}h_{n-1}^{-1}\cdots h_1^{-1}g_1 g_2\cdots g_m\,=\,1. $$ Hence by first statement left hand side cannot be reduced. This can happen only if $$h_1^{-1}g_1\,=\,1$$, i.e $$g_1\,=\,h_1.$$ Proceeding inductively we have $$m\,=\,n$$ and $$g_i\,=\,h_i$$ for all $$i\,=\,1,2,\dots ,n.$$ This shows both statements are equivalent.

Now we will show that these statements hold.

Let $$W$$ be the set of all reduced sequences in $$A*B$$. Let $$S(W)$$ be the group of permutations of $$W$$. Define $$\phi :A\rightarrow S(W)$$ as follows. If $$a=id$$, $$\phi(a)=id$$. Otherwise define $$\phi$$ as

$$ \phi(x)(g_1,g_2,\dots ,g_m) = \begin{cases} (a,g_1,g_2,\cdots ,g_m) & \text{if } g_1\in B. \\ (ag_1,g_2,\dots ,g_n) & \text{if } g_1\in A \,\,\,and \,\,\,ag_1\neq 1. \\  (g_2,g_3,\dots ,g_n) & \text{if}\, ag_1=1. \end{cases} $$

Similarly we define $$\psi :B\rightarrow S(W)$$.

It is easy to check that $$\phi$$ and $$\psi$$ are homomorphisms. Therefore by universal property of free product we will get a unique map $$\phi *\psi :A*B\rightarrow S(W)$$ and $$\phi *\psi (id)(1)=id(1)=1$$.

Now suppose $$w=g_1g_2\cdots g_n \,\,, n>0$$, where $$g_1,g_2,\dots , g_n$$ is a reduced sequence, then  $$\phi *\psi (w)(1)=(g_1,g_2,\dots , g_n). $$ Therefore $$w=1$$ in $$A*B$$ implies $$n=0$$, a contradiction.