{c}

For this sub-case, we can define the <Lie algebra> of a Lie group $G$ as the set of all matrices $M \in G$ such that for all $t \in \R$:
$$
e^{tM} \in G
$$
If we fix a given $M$ and vary $t$, we obtain a <subgroup> of $G$. This type of subgroup is known as a <one parameter subgroup>.

The immediate question is then if every element of $G$ can be reached in a unique way (i.e. is the exponential map a <bijection>). By looking at the <matrix logarithm> however we conclude that this is not the case for <real> matrices, but it is for <complex> matrices.

Examples:
* <Lie algebra of GL(n)>
* <Lie algebra of SL(2)>
* <Lie algebra of SO(3)>
* <Lie algebra of SU(2)>

TODO example it can be seen that the Lie algebra is not closed <matrix multiplication>, even though the corresponding group is by definition. But it is closed under the <Lie bracket> operation.

Lie algebra of a matrix Lie group

{c}

Based on the $L_x$,$L_y$ and $L_z$ derived at <Lie algebra of SO(3)> we can calculate the <Lie bracket> as:
$$
TODO
$$

Lie bracket of the rotation group

The one parameter subgroup of a <Lie group> for a given element $M$ of its <Lie algebra> is a <subgroup> of $G$ given by:
$$
{ e^{tM} \in G | t \in \R }
$$

Intuitively, $M$ is a direction, and $t$ is how far we move along a given direction. This intuition is especially vivid in for example in the case of the <Lie algebra of SO(3)>, the <rotation group>.

One parameter subgroups can be seen as the continuous analogue to the <cycle of an element of a group>.

One parameter subgroup

Lie algebra of SO(3)

Ciro Santilli @cirosantilli 35

 Incoming links: Lie algebra of $S O (3)$

Ciro Santilli @cirosantilli 35

 Incoming links: Lie algebra of SO(3)

 Incoming links: Lie algebra of $S O (3)$