Fundamental group: Difference between revisions
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The fundamental group of a [[based topological space]] <math>(X,x_0)</math> is defined as follows: | The fundamental group of a [[based topological space]] <math>(X,x_0)</math> is defined as follows: | ||
* As a set, it is the set of all homotopy classes of [[loop]]s at <math>x_0</math> in <math>X</math> | * As a set, it is the set of all homotopy classes of [[loop]]s at <math>x_0</math> in <math>X</math>. The homotopy class of a loop <math>f</math> is denoted <math>[f]</math>. | ||
* The group structure is obtained as follows: the composite of two loops is obtained by first traversing the first loop, and then traversing the second loop. Explicitly, if <math>f_1, f_2:[0,1] \to X</math> are the two loops, then the composite of these is the loop given by <math>t \mapsto f_1(2t)</math> for <math>0 \le t \le 1/2</math> and <math>t \mapsto f_2(2t - 1)</math> for <math>1/2 \le t \le 1</math>. Continuity of this new loop follows from the [[gluing lemma for closed subsets]]. | * The group structure is obtained as follows: the composite of two loops is obtained by first traversing the first loop, and then traversing the second loop. Explicitly, if <math>f_1, f_2:[0,1] \to X</math> are the two loops, then the composite <math>f_1 * f_2</math> of these is the loop given by <math>t \mapsto f_1(2t)</math> for <math>0 \le t \le 1/2</math> and <math>t \mapsto f_2(2t - 1)</math> for <math>1/2 \le t \le 1</math>. Continuity of this new loop follows from the [[gluing lemma for closed subsets]]. | ||
When the topological space is path-connected, the fundamental groups at any two basepoints are isomorphic. {{further|[[Actions of the fundamental group]]}} | When the topological space is path-connected, the fundamental groups at any two basepoints are isomorphic. {{further|[[Actions of the fundamental group]]}} | ||
Revision as of 03:00, 1 December 2010
Template:Group associated to based topospaces
Definition
Basic definition
The fundamental group of a based topological space is defined as follows:
- As a set, it is the set of all homotopy classes of loops at in . The homotopy class of a loop is denoted .
- The group structure is obtained as follows: the composite of two loops is obtained by first traversing the first loop, and then traversing the second loop. Explicitly, if are the two loops, then the composite of these is the loop given by for and for . Continuity of this new loop follows from the gluing lemma for closed subsets.
When the topological space is path-connected, the fundamental groups at any two basepoints are isomorphic. Further information: Actions of the fundamental group
Proof that this gives a group structure
| Condition | How it is shown | Page detailing relevant homotopy |
|---|---|---|
| existence of identity element | the identity element is the homotopy constant loop that stays at the base point. In other words, if we denote this loop by , then for any loop , the composite is homotopic to , and so is the composite . | homotopy between loop and composite with constant loop |
| existence of inverses | the inverses of a loop is the loop , i.e., the same loop done backward. In other words the composite of and this loop is homotopic to the constant loop. | homotopy between constant loop and composite of loop with inverse |
| associativity | for loops , the composite is homotopic to the composite . | homotopy between composites associated in different ways |
One nice thing about all these homotopies is that they do not depend on additional properties of the ambient space, and the homotopies do not use any points of the space other than those used in the original loops.
Related properties of topological spaces
- A simply connected space is a topological space whose fundamental group is trivial
- For a H-space and hence in particular for any space that arises as a loop space, and for any topological monoid, the fundamental group is Abelian