Continued fraction factorization: Difference between revisions
en>RedBot m r2.7.2) (Robot: Adding es:Factorización con fracciones continuas |
en>Monkbot |
||
| Line 1: | Line 1: | ||
{{distinguish|loop (algebra)}} | |||
In [[mathematics]], '''loop algebras''' are certain types of [[Lie algebra]], of particular interest in [[theoretical physics]]. | |||
If <math>\mathfrak{g}</math> is a Lie algebra, the [[tensor product]] of <math>\mathfrak{g}</math> with <math>C^\infty(S^1)</math>, | |||
:<math>\mathfrak{g}\otimes C^\infty(S^1)</math>, | |||
the [[associative algebra|algebra]] of (complex) [[smooth function]]s over the [[n-sphere|circle]] [[manifold]] S<sup>1</sup> is an infinite-dimensional Lie algebra with the [[Lie bracket of vector fields|Lie bracket]] given by | |||
:<math>[g_1\otimes f_1,g_2 \otimes f_2]=[g_1,g_2]\otimes f_1 f_2</math>. | |||
Here g<sub>1</sub> and g<sub>2</sub> are elements of <math>\mathfrak{g}</math> and f<sub>1</sub> and f<sub>2</sub> are elements of <math>C^\infty(S^1)</math>. | |||
This isn't precisely what would correspond to the [[direct product]] of infinitely many copies of <math>\mathfrak{g}</math>, one for each point in S<sup>1</sup>, because of the smoothness restriction. Instead, it can be thought of in terms of [[smooth map]] from S<sup>1</sup> to <math>\mathfrak{g}</math>; a smooth parameterized loop in <math>\mathfrak{g}</math>, in other words. This is why it is called the '''loop algebra'''. | |||
We can take the [[Fourier transform]] on this loop algebra by defining | |||
:<math>g\otimes t^n</math> | |||
as | |||
:<math>g\otimes e^{-in\sigma}</math> | |||
where | |||
:0 ≤ σ <2π | |||
is a coordinatization of S<sup>1</sup>. | |||
If <math>\mathfrak{g}</math> is a [[semisimple Lie algebra]], then a nontrivial [[Group extension#Central extension|central extension]] of its loop algebra gives rise to an affine [[Kac-Moody algebra]]. | |||
Similarly, a set of all smooth maps from S<sup>1</sup> to a [[Lie group]] G forms an infinite-dimensional Lie group (Lie group in the sense we can define [[functional derivative]]s over it) called the '''[[loop group]]'''. The Lie algebra of a loop group is the corresponding loop algebra. | |||
{{DEFAULTSORT:Loop Algebra}} | |||
[[Category:Lie algebras]] | |||
{{algebra-stub}} | |||
Revision as of 07:50, 4 February 2014
In mathematics, loop algebras are certain types of Lie algebra, of particular interest in theoretical physics.
If is a Lie algebra, the tensor product of with ,
the algebra of (complex) smooth functions over the circle manifold S1 is an infinite-dimensional Lie algebra with the Lie bracket given by
Here g1 and g2 are elements of and f1 and f2 are elements of .
This isn't precisely what would correspond to the direct product of infinitely many copies of , one for each point in S1, because of the smoothness restriction. Instead, it can be thought of in terms of smooth map from S1 to ; a smooth parameterized loop in , in other words. This is why it is called the loop algebra.
We can take the Fourier transform on this loop algebra by defining
as
where
- 0 ≤ σ <2π
is a coordinatization of S1.
If is a semisimple Lie algebra, then a nontrivial central extension of its loop algebra gives rise to an affine Kac-Moody algebra.
Similarly, a set of all smooth maps from S1 to a Lie group G forms an infinite-dimensional Lie group (Lie group in the sense we can define functional derivatives over it) called the loop group. The Lie algebra of a loop group is the corresponding loop algebra.