Double-clad fiber: Difference between revisions

Latest revision as of 17:25, 13 August 2013

In mathematics, a Poisson–Lie group is a Poisson manifold that is also a Lie group, with the group multiplication being compatible with the Poisson algebra structure on the manifold. The algebra of a Poisson–Lie group is a Lie bialgebra.

Definition

A Poisson–Lie group is a Lie group G equipped with a Poisson bracket for which the group multiplication $\mu :G\times G\to G$ with $\mu (g_{1},g_{2})=g_{1}g_{2}$ is a Poisson map, where the manifold G×G has been given the structure of a product Poisson manifold.

Explicitly, the following identity must hold for a Poisson–Lie group:

\{f_{1},f_{2}\}(gg')=\{f_{1}\circ L_{g},f_{2}\circ L_{g}\}(g')+\{f_{1}\circ R_{g^{\prime }},f_{2}\circ R_{g'}\}(g)

where f₁ and f₂ are real-valued, smooth functions on the Lie group, while g and g' are elements of the Lie group. Here, L_g denotes left-multiplication and R_g denotes right-multiplication.

If ${\mathcal {P}}$ denotes the corresponding Poisson bivector on G, the condition above can be equivalently stated as

{\mathcal {P}}(gg')=L_{g\ast }({\mathcal {P}}(g'))+R_{g'\ast }({\mathcal {P}}(g))

Note that for Poisson-Lie group always $\{f,g\}(e)=0$ , or equivalently ${\mathcal {P}}(e)=0$ . This means that non-trivial Poisson-Lie structure is never symplectic, not even of constant rank.

Homomorphisms

A Poisson–Lie group homomorphism $\phi :G\to H$ is defined to be both a Lie group homomorphism and a Poisson map. Although this is the "obvious" definition, neither left translations nor right translations are Poisson maps. Also, the inversion map $\iota :G\to G$ taking $\iota (g)=g^{-1}$ is not a Poisson map either, although it is an anti-Poisson map:

\{f_{1}\circ \iota ,f_{2}\circ \iota \}=-\{f_{1},f_{2}\}\circ \iota

for any two smooth functions $f_{1},f_{2}$ on G.

References

20 year-old Real Estate Agent Rusty from Saint-Paul, has hobbies and interests which includes monopoly, property developers in singapore and poker. Will soon undertake a contiki trip that may include going to the Lower Valley of the Omo.

My blog: http://www.primaboinca.com/view_profile.php?userid=5889534
20 year-old Real Estate Agent Rusty from Saint-Paul, has hobbies and interests which includes monopoly, property developers in singapore and poker. Will soon undertake a contiki trip that may include going to the Lower Valley of the Omo.

My blog: http://www.primaboinca.com/view_profile.php?userid=5889534

@@ Line 1: / Line 1: @@
-Ed is what people call me and my spouse doesn't like it at all. One of the extremely very best issues in the world for him is doing ballet and he'll be beginning something else along with it. Mississippi is exactly where his home is. Distributing production is exactly where my main earnings comes from and it's something I really appreciate.<br><br>my blog post ... [http://www.indosfriends.com/profile-253/info/ good psychic]
+In [[mathematics]], a '''Poisson–Lie group''' is a [[Poisson manifold]] that is also a [[Lie group]], with the group multiplication being compatible with the [[Poisson algebra]] structure on the manifold. The algebra of a Poisson–Lie group is a [[Lie bialgebra]].
+==Definition==
+A Poisson–Lie group is a Lie group ''G'' equipped with a Poisson bracket for which the group multiplication <math>\mu:G\times G\to G</math> with <math>\mu(g_1, g_2)=g_1g_2</math> is a [[Poisson map]], where the manifold ''G''×''G'' has been given the structure of a product Poisson manifold.
+Explicitly, the following identity must hold for a Poisson–Lie group:
+:<math>\{f_1,f_2\} (gg') =
+\{f_1 \circ L_g, f_2 \circ L_g\} (g') +
+\{f_1 \circ R_{g^\prime}, f_2 \circ R_{g'}\} (g)</math>
+where ''f''<sub>1</sub> and ''f''<sub>2</sub> are real-valued, smooth functions on the Lie group, while ''g'' and ''g''' are elements of the Lie group. Here, ''L<sub>g</sub>'' denotes left-multiplication and ''R<sub>g</sub>'' denotes right-multiplication.
+If <math>\mathcal{P}</math> denotes the corresponding Poisson bivector on ''G'', the condition above can be equivalently stated as
+:<math>\mathcal{P}(gg') = L_{g \ast}(\mathcal{P}(g')) + R_{g' \ast}(\mathcal{P}(g))</math>
+Note that for Poisson-Lie group always <math>\{f,g\}(e) = 0</math>, or equivalently <math>\mathcal{P}(e) = 0 </math>. This means that non-trivial Poisson-Lie structure is never symplectic, not even of constant rank.
+==Homomorphisms==
+A Poisson–Lie group homomorphism <math>\phi:G\to H</math> is defined to be both a Lie group homomorphism and a Poisson map. Although this is the "obvious" definition, neither left translations nor right translations are Poisson maps. Also, the inversion map <math>\iota:G\to G</math> taking <math>\iota(g)=g^{-1}</math> is not a Poisson map either, although it is an anti-Poisson map:
+:<math>\{f_1 \circ \iota, f_2 \circ \iota \} =
+-\{f_1, f_2\} \circ \iota</math>
+for any two smooth functions <math>f_1, f_2</math> on ''G''.
+==References==
+*{{cite book |editor1-first=H.-D. |editor1-last=Doebner |editor2-first=J.-D. |editor2-last=Hennig |title=Quantum groups |series=Proceedings of the 8th International Workshop on Mathematical Physics, Arnold Sommerfeld Institute, Claausthal, FRG |year=1989 |publisher=Springer-Verlag |location=Berlin |isbn=3-540-53503-9 }}
+*{{cite book |first=Vyjayanthi |last=Chari |first2=Andrew |last2=Pressley |title=A Guide to Quantum Groups |year=1994 |publisher=Cambridge University Press |location=Cambridge |isbn=0-521-55884-0 }}
+{{DEFAULTSORT:Poisson-Lie group}}
+[[Category:Lie groups]]
+[[Category:Symplectic geometry]]

Double-clad fiber: Difference between revisions

Latest revision as of 17:25, 13 August 2013

Definition

Homomorphisms

References

Navigation menu

Search