Flat connection: Difference between revisions
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===Symbol-free definition=== | ===Symbol-free definition=== | ||
A [[connection]] on a [[vector bundle]] over a [[differential manifold]] is said to be '''flat''' or '''integrable''' or '''curvature-free''' or '''locally flat''' if the curvature of the connection is zero everywhere. | A [[defining ingredient::connection]] on a [[defining ingredient::vector bundle]] over a [[defining ingredient::differential manifold]] is said to be '''flat''' or '''integrable''' or '''curvature-free''' or '''locally flat''' if the [[defining ingredient::curvature of a connection|curvature of the connection]] is zero everywhere. | ||
===Definition with symbols=== | ===Definition with symbols=== | ||
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===Definition in local coordinates=== | ===Definition in local coordinates=== | ||
In local coordinates, we require that the [[curvature matrix of a connection|curvature matrix]] should vanish identically; in other words: | In local coordinates, we require that the [[defining ingredient::curvature matrix of a connection|curvature matrix]] should vanish identically; in other words: | ||
<math>\Omega := d\omega + \omega \wedge \omega = 0</math> | <math>\Omega := d\omega + \omega \wedge \omega = 0</math> | ||
where <math>\omega</math> is the [[matrix of connection forms]]. | where <math>\omega</math> is the [[defining ingredient::matrix of connection forms]]. | ||
==Alternative definitions=== | ===Alternative definitions=== | ||
{{further|[[Flat connection equals module structure over differential operators]]}} | {{further|[[Flat connection equals module structure over differential operators]]}} | ||
Latest revision as of 22:01, 24 July 2011
Definition
Symbol-free definition
A connection on a vector bundle over a differential manifold is said to be flat or integrable or curvature-free or locally flat if the curvature of the connection is zero everywhere.
Definition with symbols
A connection on a vector bundle over a differential manifold is said to be flat or integrable or curvature-free or locally flat if the curvature form vanishes identically, viz for any vector fields and :
![{\displaystyle R(X,Y)=\nabla _{X}\nabla _{Y}-\nabla _{Y}\nabla _{X}-\nabla _{[X,Y]}=0}](https://wikimedia.org/api/rest_v1/media/math/render/svg/6daf24ec0a170288fdce3c20e1b127fd6b5f63b8)
Definition in local coordinates
In local coordinates, we require that the curvature matrix should vanish identically; in other words:
where is the matrix of connection forms.
Alternative definitions
Further information: Flat connection equals module structure over differential operators
Recall that one alternative view of a connection is as giving the space of sections the structure of a module over the connection algebra of . Equivalently, it is a way of giving the sheaf of sections the structure of a sheaf-theoretic module over the sheaf of connection algebras.
The connection is flat if and only if this descends to a module structure over the sheaf of differential operators. In other words, a flat connection is equivalent to a structure of as a module over the sheaf of differential operators.