Hypercycle (geometry): Difference between revisions

Revision as of 14:15, 4 December 2013

In topology, a continuous group action on a topological space X is a group action of a group G that is continuous: i.e.,

G\times X\to X,\quad (g,x)\mapsto g\cdot x

is a continuous map. Together with the group action, X is called a G-space.

If $f:H\to G$ is a continuous group homomorphism of topological groups and if X is a G-space, then H can act on X by restriction: $h\cdot x=f(h)x$ , making X a H-space. Often f is either an inclusion or a quotient map. In particular, any topological space may be thought of a G-space via $G\to 1$ (and G would act trivially.)

Two basic operations are that of taking the space of points fixed by a subgroup H and that of forming a quotient by H. We write $X^{H}$ for the set of all x in X such that $hx=x$ . For example, if we write $F(X,Y)$ for the set of continuous maps from a G-space X to another G-space Y, then, with the action $(g\cdot f)(x)=gf(g^{-1}x)$ , $F(X,Y)^{G}$ consists of f such that $f(gx)=gf(x)$ ; i.e., f is an equivariant map. We write $F_{G}(X,Y)=F(X,Y)^{G}$ . Note, for example, for a G-space X and a closed subgroup H, $F_{G}(G/H,X)=X^{H}$ .

References

John Greenlees, Peter May, Equivariant stable homotopy theory

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+In [[topology]], a '''continuous group action''' on a topological space ''X'' is a [[group action]] of a group ''G'' that is continuous: i.e.,
+:<math>G \times X \to X, \quad (g, x) \mapsto g \cdot x</math>
+is a continuous map. Together with the group action, ''X'' is called a '''''G''-space'''.
+If <math>f: H \to G</math> is a continuous group homomorphism of topological groups and if ''X'' is a ''G''-space, then ''H'' can act on ''X'' ''by restriction'': <math>h \cdot x = f(h) x</math>, making ''X'' a ''H''-space. Often ''f'' is either an inclusion or a quotient map. In particular, any topological space may be thought of a ''G''-space via <math>G \to 1</math> (and ''G'' would act trivially.)
+Two basic operations are that of taking the space of points fixed by a subgroup ''H'' and that of forming a quotient by ''H''. We write <math>X^H</math> for the set of all ''x'' in ''X'' such that <math>hx = x</math>. For example, if we write <math>F(X, Y)</math> for the set of continuous maps from a ''G''-space ''X'' to another ''G''-space ''Y'', then, with the action <math>(g \cdot f)(x) = g f(g^{-1} x)</math>,
+<math>F(X, Y)^G</math> consists of ''f'' such that <math>f(g x) = g f(x)</math>; i.e., ''f'' is an [[equivariant map]]. We write <math>F_G(X, Y) = F(X, Y)^G</math>. Note, for example, for a ''G''-space ''X'' and a closed subgroup ''H'',  <math>F_G(G/H, X) = X^H</math>.
+== References ==
+*John Greenlees, Peter May, ''[http://www.math.uchicago.edu/~may/PAPERS/Newthird.pdf Equivariant stable homotopy theory]''
+== See also ==
+*[[Lie group action]]
+{{topology-stub}}
+[[Category:Group actions]]
+[[Category:Topological groups]]

Hypercycle (geometry): Difference between revisions

Revision as of 14:15, 4 December 2013

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