Normality is quotient-transitive: Difference between revisions

Latest revision as of 14:25, 8 August 2009

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Statement

Symbolic statement

Suppose $H$ is a normal subgroup of $G$ and $K$ is a subgroup of $G$ containing $H$ , such that $K / H$ is normal in $G / H$ . Then $K$ is also normal in $G$ .

Related facts

Third isomorphism theorem is a statement describing the isomorphism types of the various quotient groups.

Generalization and other particular cases

A general version is:

Quotient-balanced implies quotient-transitive

Other particular cases are:

Related facts about normality

Proof

Hands-on proof

Pick $g \in G$ . Then the map $c_{g} : x \mapsto g x g^{- 1}$ is an inner automorphism of $G$ , hence sends $H$ to itself and induces an automorphism of $G / H$ . More importantly, the induced automorphism on $G / H$ is also an inner automorphism, by the image of $g$ under the quotient map $G \to G / H$ . Since $K / H$ is normal in $G / H$ , the induced map on $G / H$ preserves the subgroup $K / H$ . Hence $c_{g}$ sends $K$ to $K$ .

Property-theoretic proof

@@ Line 7: / Line 7: @@
 Suppose <math>H</math> is a [[normal subgroup]] of <math>G</math> and <math>K</math> is a subgroup of <math>G</math> containing <math>H</math>, such that <math>K/H</math> is normal in <math>G/H</math>. Then <math>K</math> is also normal in <math>G</math>.
+==Related facts==
+* [[Third isomorphism theorem]] is a statement describing the isomorphism types of the various quotient groups.
+===Generalization and other particular cases===
+A general version is:
+[[Quotient-balanced implies quotient-transitive]]
+Other particular cases are:
+* [[Characteristicity is quotient-transitive]]
+* [[Strict characteristicity is quotient-transitive]]
+* [[Full invariance is quotient-transitive]]
+===Related facts about normality===
+* [[Normality is strongly join-closed]]
+* [[Normality is not transitive]]
+* [[Normality satisfies image condition]]
+* [[Normality satisfies inverse image condition]]
 ==Proof==