Let R be a ring and G be a group and $H \unlhd G$ , where RG is the group ring. Define $\widehat{H}= \sum_{h \in H } h$. And $e_H$ defined below is central idempotent. Now I was understanding the following proof..
Now I have some problem in understanding the group homomorphism $\phi : G \to Ge_H$ defined $g \to ge_H$ has $ker(\phi)= H$.
Conceptual doubts-
1) First I guess I am not clear on how $Ge_H$ is defined as a group. According to me $Ge_H$ is a a subset of Group ring $RG$ containing element of type $\frac{1} {|H|}(1_R.gh_1+1_Rg.h_2+ \ldots +1_Rg.h_k+\ldots)\ \forall\ g \in G$. So if it is a group it should be group under + in $RG$ so let $ x=\frac{1} {|H|}(1_R.gh_1+1_Rg.h_2+ \ldots +1_Rg.h_k+\ldots)\ \text{and }\ y= \frac{1} {|H|}(1_R.g'h_1+1_Rg'.h_2+ \ldots +1_Rg'.h_k+\ldots)\$$ be two different elements of $Ge_H$. Then $x+y= \frac {1} {|H|}(1_R.gh_1+1_Rg.h_2+ \ldots +1_Rg.h_k+\ldots)+(1_R.g'h_1+1_Rg'.h_2+ \ldots +1_Rg'.h_k+\ldots)) $, so why is closure satisfied? What is the correct operation on $Ge_H$ ?
(Clearly I am doing some mistake here, I guess I am not using correct operation, but this the operation in RG is considered a group, so what is I am getting wrong here? Please help me understand it.)
2) If $h \in H$ then $\phi(h)=he_H=e_H$. So $e_H$ should be the identity of $Ge_H$ (If I can see it as a group under some appropriate operation). How?
3) Also what does $ {|H|} $ is invertible in a ring means. Am I right that it means if there is some element $a$ in R s.t. when $a$ is added |H| times it gives 1, because |H| is a integer and Ring can have elements as matrices so obviously, |H| does not have to be in R , and this must be the meaning of being invertible in R.
Please clear these basic doubts of mine. I will be highly thankful. I am studying on my own and these things are not cleared in the book. Untill these are clear, I am stuck.