# Curvature form

In differential geometry, the curvature form describes curvature of a connection on a principal bundle. It can be considered as an alternative to or generalization of the curvature tensor in Riemannian geometry.

## Definition

Let G be a Lie group with Lie algebra ${\mathfrak {g}}$ , and PB be a principal G-bundle. Let ω be an Ehresmann connection on P (which is a ${\mathfrak {g}}$ -valued one-form on P).

Then the curvature form is the ${\mathfrak {g}}$ -valued 2-form on P defined by

$\Omega =d\omega +{1 \over 2}[\omega \wedge \omega ]=D\omega .$ Here $d$ stands for exterior derivative, $[\cdot \wedge \cdot ]$ is defined in the article "Lie algebra-valued form" and D denotes the exterior covariant derivative. In other terms,

$\,\Omega (X,Y)=d\omega (X,Y)+[\omega (X),\omega (Y)]$ where X, Y are tangent vectors to P.

There is also another expression for Ω: if X, Y are horizontal vector fields on P, then

$\sigma \Omega (X,Y)=-\omega ([X,Y])=-[X,Y]+h[X,Y]$ where hZ means the horizontal component of Z, on the right we identified a vertical vector field and a Lie algebra element generating it (fundamental vector field), and $\sigma \in \{1,2\}$ is the inverse of the normalization factor used by convention in the formula for the exterior derivative.

A connection is said to be flat if its curvature vanishes: Ω = 0. Equivalently, a connection is flat if the structure group can be reduced to the same underlying group but with the discrete topology. See also: flat vector bundle.

### Curvature form in a vector bundle

If EB is a vector bundle, then one can also think of ω as a matrix of 1-forms and the above formula becomes the structure equation of E. Cartan:

$\,\Omega =d\omega +\omega \wedge \omega ,$ where $\wedge$ is the wedge product. More precisely, if $\omega _{\ j}^{i}$ and $\Omega _{\ j}^{i}$ denote components of ω and Ω correspondingly, (so each $\omega _{\ j}^{i}$ is a usual 1-form and each $\Omega _{\ j}^{i}$ is a usual 2-form) then

$\Omega _{\ j}^{i}=d\omega _{\ j}^{i}+\sum _{k}\omega _{\ k}^{i}\wedge \omega _{\ j}^{k}.$ For example, for the tangent bundle of a Riemannian manifold, the structure group is O(n) and Ω is a 2-form with values in the Lie algebra of O(n), i.e. the antisymmetric matrices. In this case the form Ω is an alternative description of the curvature tensor, i.e.

$\,R(X,Y)=\Omega (X,Y),$ using the standard notation for the Riemannian curvature tensor.

## Bianchi identities

If $\theta$ is the canonical vector-valued 1-form on the frame bundle, the torsion $\Theta$ of the connection form $\omega$ is the vector-valued 2-form defined by the structure equation

$\Theta =d\theta +\omega \wedge \theta =D\theta ,$ where as above D denotes the exterior covariant derivative.

The first Bianchi identity takes the form

$D\Theta =\Omega \wedge \theta .$ The second Bianchi identity takes the form

$\,D\Omega =0$ and is valid more generally for any connection in a principal bundle.

## See also

This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.