Linear connection: Difference between revisions

Latest revision as of 16:03, 26 May 2025

This lives as an element of: the space of
$R$
-bilinear maps
$Γ (T M) \times Γ (T M) \to Γ (T M)$

Definition

Given data

A connected differential manifold $M$ with tangent bundle denoted by $T M$

Definition part (pointwise form)

A linear connection is a smooth choice $\nabla$ of the following: at each point $p \in M$ , there is a map $p \nabla : T_{p} (M) \times Γ (T M) \to T_{p} (M)$ , satisfying some conditions. The map is written as $p \nabla_{X} (v)$ where $X \in T_{p} (M)$ and $v \in Γ (T M)$ .

It is $R$ -linear in $X$ (that is, in the $T_{p} (M)$ coordinate).
It is $R$ -linear in $Γ (T M)$ (viz the space of sections on $T M$ ).
It satisfies the following relation called the Leibniz rule:

$p \nabla_{X} (f v) = (X f) (p) (v) + f (p)^{p} \nabla_{X} (v)$

Definition part (global form)

A linear connection is a map $\nabla : Γ (T M) \times Γ (T M) \to Γ (T M)$ , satisfying the following:

It is $C^{\infty}$ -linear in the first $Γ (T M)$
it is $R$ -linear in the second $Γ (T M)$
It satisfies the following relation called the Leibniz rule:

$\nabla_{X} (f v) = (X f) (v) + f \nabla_{X} (v)$

where $f$ is a scalar function on the manifold and $f v$ denotes scalar multiplication of $v$ by $f$ .

Generalizations

The notion of linear connection can be generalized to the more general notion of a connection, where the second $T M$ is replaced by an arbitrary vector bundle $E$ over $M$ .

Operations on a linear connection

Torsion of a linear connection

Further information: torsion of a linear connection

The torsion of a linear connection $\nabla$ is denoted as $τ (\nabla)$ . It is a $(1, 2)$ -tensor defined as:

$τ (\nabla) (X, Y) = \nabla_{X} Y - \nabla_{Y} X - [X, Y]$ .

A connection whose torsion is zero is termed a torsion-free linear connection.

Note that torsion makes sense only for linear connections.

Curvature of a linear connection

Further information: Riemann curvature tensor

The curvature of a linear connection $\nabla$ is denoted as $R_{\nabla}$ . It is defined as:

$R_{\nabla} (X, Y) = \nabla_{X} \nabla_{Y} - \nabla_{Y} \nabla_{X} - \nabla_{[X, Y]}$

The notion of curvature actually makes sense for any connection.

@@ Line 9: / Line 9: @@
 ===Definition part (pointwise form)===
-A '''linear connection''' is a smooth choice <math>\nabla</math> of the following: at each point <math>p \in M</math>, there is a map <math>{}^p\nabla: T_p(M) \times \Gamma(TM) \to T_p(M)</math>, satisfying some conditions. The map is written as <math>{}^p\nabla_X(v)</math> where <math>X \in T_p(M)</math> and <math>v \in \Gamma(E)</math>.
+A '''linear connection''' is a smooth choice <math>\nabla</math> of the following: at each point <math>p \in M</math>, there is a map <math>{}^p\nabla: T_p(M) \times \Gamma(TM) \to T_p(M)</math>, satisfying some conditions. The map is written as <math>{}^p\nabla_X(v)</math> where <math>X \in T_p(M)</math> and <math>v \in \Gamma(TM)</math>.
 * It is <math>\R</math>-linear in <math>X</math> (that is, in the <math>T_p(M)</math> coordinate).
-* It is <math>\R</math>-linear in <math>\Gamma(TM)</math> (viz the space of sections on <math>E</math>).
+* It is <math>\R</math>-linear in <math>\Gamma(TM)</math> (viz the space of sections on <math>TM</math>).
 * It satisfies the following relation called the Leibniz rule:
@@ Line 25: / Line 25: @@
 * It satisfies the following relation called the Leibniz rule:
-<math>\nabla_X(fv) = (Xf) (v) f \nabla_X(v) </math>
+<math>\nabla_X(fv) = (Xf) (v) + f \nabla_X(v) </math>
 where <math>f</math> is a scalar function on the manifold and <math>fv</math> denotes scalar multiplication of <math>v</math> by <math>f</math>.