Holonomy group: Difference between revisions

Definition

Let ${\displaystyle M}$ be a differential manifold, ${\displaystyle E}$ a vector bundle over ${\displaystyle M}$ and ${\displaystyle \nabla }$ a connection for ${\displaystyle E}$. For a point ${\displaystyle m\in M}$ the holonomy group at ${\displaystyle m}$ is the subgroup of ${\displaystyle GL(E_{p})}$ comprising those linear transformations that arise as the holonomy of a loop at ${\displaystyle m}$.

If the differential manifold is path-connected, the holonomy groups at distinct points are conjugate as subgroups of ${\displaystyle GL(E_{p})}$ so we can talk of the holonomy group.

Related notions

• Restricted holonomy group
• Holonomy group of Riemannian metric

Facts

Reduction of structure group to holonomy group

Any path-connected differential manifold can be treated as a principal bundle with structure group being the holonomy group. The description is as follows:

• Pick (arbitrarily) a basis at a particular point ${\displaystyle p}$
• Now, for each point ${\displaystyle m}$, the fibre at that point is the set of all bases at ${\displaystyle m}$ that can arise from the basis at ${\displaystyle p}$ by means of transport along a curve using the connection ${\displaystyle \nabla }$.
• In particular, any two bases at ${\displaystyle m}$ differ by the holonomy of a loop, which lies in ${\displaystyle H}$. Thus ${\displaystyle H}$ acts freely and transitively on the fibre at each point.

Moreover the holonomy group is the smallest group to which the structure group can be reduced (for the same reasons).