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Homomorphism

Definition

Given groups G1,G2G_1, G_2 with operations *1,*2*_1, *_2, a map ϕ:G1G2\phi: G_1 \to G_2 is said to be a homomorphism if the group operation is preserved, i.e. g,hG1:ϕ(g*1h)=ϕ(g)*2ϕ(h)\forall g,h \in G_1: \phi(g *_1 h) = \phi(g) *_2 \phi(h).

Criterion

g,hG1:ϕ(gh)=ϕ(g)ϕ(h)\forall g,h \in G_1: \phi(gh) = \phi(g)\phi(h). This is the same as the definition, and is usually the most efficient thing to show. The other properties such as preserving the identity fall out easily.

Properties

Basic properties

The identity is preserved, since ϕ(e1)=ϕ(e1e1)=ϕ(e1)ϕ(e1)\phi(e_1) = \phi(e_1 e_1) = \phi(e_1) \phi(e_1). Inverses are also preserved.

Given homomorphisms ϕ:G1G2\phi: G_1 \to G_2 and ψ:G2G3\psi: G_2 \to G_3, their composition ϕψ:G1G3\phi \circ \psi: G_1 \to G_3 is also a homomorphism.

More interesting properties

The kernel ker(ϕ)=ϕ1(e2)\ker(\phi) = \phi^{-1}(e_2), is a normal subgroup of G1G_1. The image imϕ=ϕ(G1)\mathrm{im}\phi = \phi(G_1) is a subgroup of G2G_2.

The homomorphism ϕ\phi is injective if and only if its kernel is trivial.

Types

A bijective homomorphism is called an isomorphism.

An isomorphism ϕ:GG\phi: G \to G is called an automorphism. The automorphisms of the group form a group AutG\mathrm{Aut}G.

Related theorems

The first isomorphism theorem gives an isomorphism G1/kerϕimϕG_1 / \ker\phi \cong \mathrm{im}\phi

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all these pages adapted with probably insufficient credit from my university's lecture notes