Torsion-free linear connection: Difference between revisions

Revision as of 23:48, 12 April 2008

Definition

Symbol-free definition

A linear connection on a differential manifold is said to be torsion-free or symmetric if it satisfies the following equivalent conditions:

Its torsion is zero
Whenever two vector fields are such that their Lie bracket is zero, then the covariant derivative of either with respect to the other are equal.

Definition with symbols

A linear connection $\nabla$ on a differential manifold $M$ is said to be torsion-free or symmetric if it satisfies the following equivalent conditions:

The torsion of $\nabla$ is a zero map, viz:

$\tau (\nabla )=(X,Y)\mapsto \nabla _{X}Y-\nabla _{Y}X-[X,Y]=0$

Whenever $X$ and $Y$ are vector fields on an open subset $U\subset M$ such that $[X,Y]=0$ on $U$ , then:

$\nabla _{X}Y=\nabla _{Y}X$

Definition in local coordinates

In local coordinates, a linear connection is torsion-free if the Christoffel symbols $\Gamma _{ij}^{k}$ are symmetric in $i$ and $j$ .

Facts

Set of all torsion-free linear connections

Further information: Affine space of torsion-free linear connections Recall that the set of all linear connections is an affine space, viz a translate of a linear subspace (the linear subspace being the maps that are tensorial in both variables).

The set of torsion-free linear connections is an affine subspace of this, in the sense that any affine combination of torsion-free linear connections is again a torsion-free linear connection.

The corresponding linear subspace for torsion-free linear connections are the symmetric 2-tensors.

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 ===Symbol-free definition===
-A [[linear connection]] on a [[differential manifold]] is said to be '''torsion-free''' if its [[torsion of a linear connection|torsion]] is zero.
+A [[linear connection]] on a [[differential manifold]] is said to be '''torsion-free''' or '''symmetric''' if it satisfies the following equivalent conditions:
+* Its [[torsion of a linear connection|torsion]] is zero
+* Whenever two vector fields are such that their Lie bracket is zero, then the covariant derivative of either with respect to the other are equal.
 ===Definition with symbols===
-A [[linear connection]] <math>\nabla</math> on a [[differential manifold]] <math>M</math> is said to be '''torsion-free''' if the [[torsion of a linear connection|torsion]] of <math>\nabla</math> is a zero map, viz:
+A [[linear connection]] <math>\nabla</math> on a [[differential manifold]] <math>M</math> is said to be '''torsion-free''' or '''symmetric''' if it satisfies the following equivalent conditions:
+* The [[torsion of a linear connection|torsion]] of <math>\nabla</math> is a zero map, viz:
+<math>\tau(\nabla) = (X,Y) \mapsto \nabla_XY - \nabla_YX - [X,Y] = 0</math>
+* Whenever <math>X</math> and <math>Y</math> are vector fields on an open subset <math>U \subset M</math> such that <math>[X,Y]= 0</math> on <math>U</math>, then:
+<math>\nabla_X Y = \nabla_YX</math>
-<math>\tau(\nabla) = (X,Y) \mapsto \nabla_XY - \nabla_YX - [X,Y]</math>
+===Definition in local coordinates===
+In local coordinates, a linear connection is torsion-free if the Christoffel symbols <math>\Gamma_{ij}^k</math> are symmetric in <math>i</math> and <math>j</math>.
 ==Facts==