Lie Group: Difference between revisions
Added definitions for Lie groups. |
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== Definition == | == Definition == | ||
A group G, is a Lie group if G is a smooth manifold such that group multiplication $m:G\times G\to G$ and inversion $i:G\to G$ are smooth maps. | |||
== Morphisms == | == Morphisms == | ||
A morphism of Lie groups $\phi:G\to H$ is a smooth group homomorphism. A Lie group morphism is an isomorphism if it is a diffeomorphism that is also a group homomorphism. | |||
Lie groups and Lie group morphisms form a category. | |||
== Examples == | == Examples == | ||
Revision as of 07:52, 22 January 2026
Definition
A group G, is a Lie group if G is a smooth manifold such that group multiplication $m:G\times G\to G$ and inversion $i:G\to G$ are smooth maps.
Morphisms
A morphism of Lie groups $\phi:G\to H$ is a smooth group homomorphism. A Lie group morphism is an isomorphism if it is a diffeomorphism that is also a group homomorphism.
Lie groups and Lie group morphisms form a category.
Examples
Let $V$ be a vector space. Then $(V, +)$ is a Lie group.
$(\Z, +)$ is a $0$-dimensional Lie group.
$\R / \Z$ is a $1$-dimensional Lie group.
$S^3 = \{(x_1, y_1, x_2, y_2) \in \R^4: \Vert-\Vert = 1\}$ with group structure $(z_1, z_2) \cdot (z_3, z_4) := (z_1 z_3 - z_2 \overline{z_4}, z_1 z_4 - z_2 \overline{z_3})$ where we treat $\R^4$ as $\C^2$.
Matrix Lie Groups
$GL_n(\R)$