Group homomorphism/Introduction/Section

Definition

Let ${}(G,\circ ,e_{G})$ and ${}(H,\circ ,e_{H})$ denote groups. A mapping

\psi \colon G\longrightarrow H

is called group homomorphism, if the equality

{}\psi (g\circ g')=\psi (g)\circ \psi (g')\,

holds for all

{}g,g'\in G

.

The set of all group homomorphisms from ${}G$ to ${}H$ is denoted by

\operatorname {Hom} _{}{\left(G,H\right)}.

Linear mappings between vector spaces are in particular group homomorphisms. The following two lemmas follow directly from the definition.

Lemma

Let ${}G$ and ${}H$ denote groups, and let ${}\varphi \colon G\rightarrow H$ be a group homomorphism. Then ${}\varphi (e_{G})=e_{H}$ and ${}(\varphi (g))^{-1}=\varphi {\left(g^{-1}\right)}$ for every

{}g\in G

.

Proof

To prove the first statement, consider

{}\varphi (e_{G})=\varphi (e_{G}e_{G})=\varphi (e_{G})\varphi (e_{G})\,.

Multiplication with ${}\varphi (e_{G})^{-1}$ yields ${}e_{H}=\varphi (e_{G})$ .
To prove the second claim, we use

{}\varphi {\left(g^{-1}\right)}\varphi (g)=\varphi {\left(g^{-1}g\right)}=\varphi (e_{G})=e_{H}\,.

This means that ${}\varphi {\left(g^{-1}\right)}$ has the property that characterizes the inverse element of ${}\varphi (g)$ . Since the inverse element in a group is, due to fact, uniquely determined, we must have ${}\varphi {\left(g^{-1}\right)}=(\varphi (g))^{-1}$ .

\Box

Lemma

Let ${}F,G,H$ denote

groups. Then the following properties hold.

The identity
$\operatorname {Id} \colon G\longrightarrow G$

is a group homomorphism.
If ${}\varphi :F\rightarrow G$ and ${}\psi :G\rightarrow H$ are group homomorphisms, then the composition ${}\psi \circ \varphi \colon F\rightarrow H$ is a group homomorphism.
For a subgroup ${}F\subseteq G$ , the inclusion ${}F\hookrightarrow G$ is a group homomorphism.
Let ${}\{e\}$ be the trivial group. Then the mapping ${}\{e\}\rightarrow G$ that sends ${}e$ to ${}e_{G}$ is a group homomorphism. Moreover, the (constant) mapping ${}G\rightarrow \{e\}$ is a group homomorphism.

Proof

This is trivial.

\Box

Example

Let ${}d\in \mathbb {N}$ be fixed. The mapping

\mathbb {Z} \longrightarrow \mathbb {Z} ,n\longmapsto dn,

is a group homomorphism. This follows immediately from the distributive law. For ${}d\geq 1$ , this mapping is injective, and the image is the subgroup ${}\mathbb {Z} d\subseteq \mathbb {Z}$ . For ${}d=0$ , we have the zero mapping. For ${}d=1$ , the mapping is the identity. For ${}d\geq 2$ , the mapping is not surjective.

Example

Let ${}d\in \mathbb {N} _{+}$ . We consider the set

{}\mathbb {Z} /(d)=\{0,1,\ldots ,d-1\}\,,

together with the addition described in exercise, which makes it a group. The mapping

\varphi \colon \mathbb {Z} \longrightarrow \mathbb {Z} /(d)

that sends an integer number ${}n$ to its remainder after division by ${}d$ is a group homomorphism. For, if ${}m=ad+r$ and ${}n=bd+s$ are given with ${}0\leq r,s<d$ , then

{}m+n=(a+b)d+r+s\,.

Here, it may happen that ${}r+s\geq d$ . In this case,

{}\varphi (m+n)=r+s-d\,,

and this coincides with the addition of ${}r$ and ${}s$ in ${}\mathbb {Z} /(d)$ . This mapping is surjective, but not injective.

Example

For a field ${}K$ and ${}n\in \mathbb {N} _{+}$ , the determinant

\det \colon \operatorname {GL} _{n}\!{\left(K\right)}\longrightarrow K^{\times },M\longmapsto \det M,

is a group homomorphism. This follows from the multiplication theorem for the determinant and fact.

Example

The assignment

S_{n}\longrightarrow \{1,-1\},\pi \longmapsto \operatorname {sgn} (\pi ),

where ${}S_{n}$ denotes the permutation group for ${}n$ elements, is a group homomorphism, due to fact.

Lemma

Let ${}G$ denote a group. Then there is a correspondence between group elements ${}g\in G$ and group homomorphisms ${}\varphi$ from ${}\mathbb {Z}$ to ${}G$ , given by

g\longmapsto (n\mapsto g^{n}){\text{ and }}\varphi \longmapsto \varphi (1).

Proof

Let ${}g\in G$ be fixed. That the mapping

\varphi _{g}\colon \mathbb {Z} \longrightarrow G,n\longmapsto g^{n},

is a group homomorphism, is just a reformulation of the exponential laws. Because of ${}\varphi _{g}(1)=g^{1}=g$ , we obtain from the power mapping ${}\varphi _{g}$ the group element back. Moreover, a group homomorphism ${}\varphi \colon \mathbb {Z} \rightarrow G$ is uniquely determined by ${}\varphi (1)$ , as ${}\varphi (n)=(\varphi (1))^{n}$ for ${}n$ positive, and ${}\varphi (n)={\left((\varphi (1))^{-1}\right)}^{-n}$ for ${}n$ negative must hold.

\Box

This lemma can be stated quickly by saying ${}G\cong \operatorname {Hom} _{}{\left(\mathbb {Z} ,G\right)}$ . It is more difficult to characterize the group homomorphisms from a group ${}G$ to ${}\mathbb {Z}$ . The group homomorphisms from ${}\mathbb {Z}$ to ${}\mathbb {Z}$ are just the multiplications with a fixed integer number ${}a$ , that is,

\mathbb {Z} \longrightarrow \mathbb {Z} ,x\longmapsto ax.