Difference between revisions of "Orbit"
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− | An '''orbit''' is part of a [[set]] on which a [[group]] acts. | + | An '''orbit''' is part of a [[set]] on which a [[group]] [[group action|acts]]. |
Let <math>G</math> be a group, and let <math>S</math> be a <math>G</math>-set. The '''orbit''' of an element <math>x\in S</math> is the set <math>Gx</math>, i.e., the set of [[conjugate (group theory) | conjugate]]s of <math>x</math>, or the set of elements <math>y</math> in <math>S</math> for which there exists <math>\alpha \in G</math> for which <math>\alpha x = y</math>. | Let <math>G</math> be a group, and let <math>S</math> be a <math>G</math>-set. The '''orbit''' of an element <math>x\in S</math> is the set <math>Gx</math>, i.e., the set of [[conjugate (group theory) | conjugate]]s of <math>x</math>, or the set of elements <math>y</math> in <math>S</math> for which there exists <math>\alpha \in G</math> for which <math>\alpha x = y</math>. | ||
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* [[Stabilizer]] | * [[Stabilizer]] | ||
* [[Orbit-stabilizer theorem]] | * [[Orbit-stabilizer theorem]] | ||
+ | * [[Group action]] | ||
[[Category:Group theory]] | [[Category:Group theory]] |
Revision as of 15:33, 7 September 2008
An orbit is part of a set on which a group acts.
Let be a group, and let be a -set. The orbit of an element is the set , i.e., the set of conjugates of , or the set of elements in for which there exists for which .
For , the mapping is sometimes known as the orbital mapping defined by ; it is a homomorphism of the -set (with action on itself, by left translation) into ; the image of is the orbit of . We say that acts freely on if the orbital mapping defined by is injective, for all .
The set of orbits of is the quotient set of under the relation of conjugation. This set is denoted , or . (Sometimes the first notation is used when acts on the left, and the second, when acts on the right.)
Let be a set acting on from the right, and let be a normal subgroup of . Then acts on from the right, under the action , for . ( acts trivially on this set, so .) Consider the canonical mapping . The inverse images of elements of under are the orbits of under action of ; thus on passing to the quotient, defines an isomorphism from to .
Suppose and are groups, and acts on on the left, and on the right; suppose furthermore that the operations of and commute, i.e., for all , , , Let be the opposite group of ; then the actions of and on define a left action of on . The set is denoted . Since and are normal subgroups of , by the previous paragraph, the -sets , , are isomorphic and identitfied with each other.
Let be a group, and a subgroup of ; let it act on from the right. Then the set is the set of left cosets mod .
If is a group and are subgroups of , then the set is called the set of double cosets mod and .