Abstract Algebra/Composition series

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Proof:

We prove the theorem by induction over ${\displaystyle |G|}$.

1. ${\displaystyle |G|=1}$. In this case, ${\displaystyle G}$ is the trivial group, and ${\displaystyle M_1}$ with ${\displaystyle M_1=G}$ is a composition series of ${\displaystyle G}$.

2. Assume the theorem is true for all ${\displaystyle n\in \mathbb{N}}$, ${\displaystyle n<|G|}$.

Since the trivial subgroup ${\displaystyle \{e\}\subset G}$ is a normal subgroup of ${\displaystyle G}$, the set of proper normal subgroups of ${\displaystyle G}$ is not empty. Therefore, we may choose a proper normal subgroup ${\displaystyle N}$ of maximum cardinality. This must also be a maximal proper normal subgroup, since any group in which it is contained must have at least equal cardinality, and thus, if ${\displaystyle M}$ is normal such that

${\displaystyle N⊊M⊊G}$

, then

${\displaystyle |M|>|N|}$

, which is why ${\displaystyle N}$ is not a proper normal subgroup of maximal cardinality.

Due to theorem 2.6.?, ${\displaystyle G/N}$ is simple. Further, since ${\displaystyle |N|<|G|}$, the induction hypothesis implies that there exists a composition series of ${\displaystyle N}$, which we shall denote by ${\displaystyle N_2,\dots ,N_n}$, where

${\displaystyle \{e\}=N_n◃N_{n-1}◃\cdots ◃N_2=N}$

. But then we have

${\displaystyle \{e\}=N_n◃\cdots ◃N_2=N◃N_1:=G}$

, and further for each ${\displaystyle m\in \{1,\dots ,n-1\}}$:

${\displaystyle N_m/N_{m+1}}$ is simple.

Thus, ${\displaystyle N_1,\dots ,N_n}$ is a composition sequence of ${\displaystyle G}$.${\displaystyle ◻}$

Our next goal is to prove that given two normal sequences of a group, we can find two 'refinements' of these normal sequences which are equivalent. Let us first define what we mean by a refinement of a normal sequence.

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Proof:

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Proof:

Due to theorem 2.6.?, all the elements of ${\displaystyle \{N_1,\dots ,N_n\}}$ must be pairwise different, and the same holds for the elements of ${\displaystyle \{M_1,\dots ,M_k\}}$.

Due to theorem 2.7.4, there exist refinements ${\displaystyle {N_1}^{\prime },\dots ,{N_m}^{\prime }}$ of ${\displaystyle N_1,\dots ,N_n}$ and ${\displaystyle {M_1}^{\prime },\dots ,{M_l}^{\prime }}$ of ${\displaystyle M_1,\dots ,M_k}$ such that ${\displaystyle {N_1}^{\prime },\dots ,{N_m}^{\prime }}$ and ${\displaystyle {M_1}^{\prime },\dots ,{M_l}^{\prime }}$ are equivalent.

But these refinements satisfy

${\displaystyle \{{N_1}^{\prime },\dots ,{N_m}^{\prime }\}=\{N_1,\dots ,N_n\}}$

and

${\displaystyle \{{M_1}^{\prime },\dots ,{M_l}^{\prime }\}=\{M_1,\dots ,M_k\}}$

, since if this were not the case, we would obtain a contradiction to theorem 2.6.?.

We now choose a bijection ${\displaystyle \sigma :\{1,\dots ,m\}\to \{1,\dots ,m\}}$ such that for all ${\displaystyle j\in \{1,\dots ,m-1\}}$:

${\displaystyle N_j/N_{j+1}\cong M_{\sigma (j)}/M_{\sigma (j)+1}}$

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