Curvature of a connection

This curvature is also sometimes known as the Riemann curvature tensor. However, the latter term is usually reserved for situations where we have a linear connection, in particular, the Riemann curvature tensor arising from the Levi-Civita connection for a Riemannian or pseudo-Riemannian manifold

Definition

Given data

A connected differential manifold $M$
A vector bundle $E$ over $M$
A connection $\nabla$ for $E$

Definition part

The curvature of $\nabla$ is defined as the map:

$R(X,Y)=\nabla _{X}\circ \nabla _{Y}-\nabla _{Y}\circ \nabla _{X}-\nabla _{[X,Y]}$

where $X,Y\in \Gamma$

Note that $R(X,Y)$ itself outputs a linear map $\Gamma (E)\to \Gamma (E)$ . We can thus write this as:

$R(X,Y)Z=\nabla _{X}(\nabla _{Y}Z)-\nabla _{Y}(\nabla _{X}Z)-\nabla _{[X,Y]}Z$

In local coordinates

Further information: curvature matrix of a connection

Consider a system of local coordinate charts for $M$ such that the vector bundle $E$ is trivial on each chart. For any connection $\nabla$ , we can write a matrix that, in local coordinates, describes the curvature of $\nabla$ . This matrix is sometimes denoted as $\Omega$ , and is defined by:

$\Omega :=d\omega +\omega \wedge \omega$

Here, $\omega$ is a matrix of connection forms.

In the linear case

In the special case where $E=TM$ (the case of a linear connection) we get that $X,Y,Z\in \Gamma (TM)$ . We can thus think of this map as a (1,3)-tensor because it takes as input three vector fields and outputs one vector field.

Properties

Tensoriality

Further information: Curvature is tensorial

The curvature is tensorial in all three arguments. This is best proved by proving $C^{\infty }$ -linearity in all arguments, via a computation.

Antisymmetry

Further information: Curvature is antisymmetric in first two variables

We have the following identity:

$R(X,Y)=-R(Y,X)$