Difference between revisions of "Conjugate (group theory)"

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Let <math>G</math> be a [[group]] operating on a [[set]] <math>S</math>.  An element <math>y\in S</math> ''conjugate'' to an element <math>x\in S</math> if there exists an element <math>\alpha \in G</math> such that <math>y = \alpha x</math>.  The relation of conjugacy is an [[equivalence relation]].  The set of conjugates of an element <math>x</math> of <math>S</math> is called the [[orbit]] of <math>x</math>.
 
Let <math>G</math> be a [[group]] operating on a [[set]] <math>S</math>.  An element <math>y\in S</math> ''conjugate'' to an element <math>x\in S</math> if there exists an element <math>\alpha \in G</math> such that <math>y = \alpha x</math>.  The relation of conjugacy is an [[equivalence relation]].  The set of conjugates of an element <math>x</math> of <math>S</math> is called the [[orbit]] of <math>x</math>.
  
Note that this definition conforms to the notion of [[complex conjugate]].  Indeed, under the group of [[field]] [[automorphism]]s on the complexe numbers that do not change the reals, the orbit of a complex number <math>z</math> is the set <math>\{z, \overbar{z}\}</math>.
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Note that this definition conforms to the notion of [[complex conjugate]].  Indeed, under the group of [[field]] [[automorphism]]s on the complexe numbers that do not change the reals, the orbit of a complex number <math>z</math> is the set <math>\{z, \bar{z}\}</math>.
  
 
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Revision as of 17:58, 20 May 2008

Let $G$ be a group operating on a set $S$. An element $y\in S$ conjugate to an element $x\in S$ if there exists an element $\alpha \in G$ such that $y = \alpha x$. The relation of conjugacy is an equivalence relation. The set of conjugates of an element $x$ of $S$ is called the orbit of $x$.

Note that this definition conforms to the notion of complex conjugate. Indeed, under the group of field automorphisms on the complexe numbers that do not change the reals, the orbit of a complex number $z$ is the set $\{z, \bar{z}\}$.

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