Connection is module structure over connection algebra

Statement

Let ${\displaystyle E}$ be a vector bundle over a differential manifold ${\displaystyle M}$. Then, a connection on ${\displaystyle E}$ is equivalent to giving ${\displaystyle \Gamma (E)}$ (the vector space of sections of ${\displaystyle E}$) the structure of a module over the connection algebra of ${\displaystyle M}$. Equivalently, it gives ${\displaystyle {\mathcal {E}}}$ (the sheaf of sections of ${\displaystyle E}$) the structure of a module over the sheaf of connection algebras over ${\displaystyle M}$.

Definitions used

Connection

Further information: Connection

Connection algebra

Further information: Connection algebra

Proof

From a connection to a module structure

The outline of the proof is as follows:

• We first show that a connection gives an action of the first-order differentiable operators on the space of sections.
• Next, we show that the Leibniz rule property of connections allows us to extend this to a well-defined action of the connection algebra.

Given: A manifold ${\displaystyle M}$, a vector bundle ${\displaystyle E}$ over ${\displaystyle M}$, a connection ${\displaystyle \nabla }$ on ${\displaystyle E}$. ${\displaystyle B}$ is the algebra of smooth fiber-preserving maps from ${\displaystyle \Gamma (E)}$ to ${\displaystyle \Gamma (E)}$. ${\displaystyle {\mathcal {D}}^{1}(M)}$ is the Lie algebra of first-order differential operators on ${\displaystyle M}$ and ${\displaystyle {\mathcal {C}}(M)}$ is the connection algebra on ${\displaystyle M}$.

To prove: ${\displaystyle \nabla }$ gives rise to a homomorphism from ${\displaystyle {\mathcal {C}}(M)}$ to ${\displaystyle B}$.

Proof: ${\displaystyle \nabla }$ gives rise to a map:

${\displaystyle f_{\nabla }:D^{1}(M)\to B}$

as follows:

${\displaystyle f_{\nabla }(X+m(g))=s\mapsto \nabla _{X}(s)+(gs)}$.

First observe that the map sends ${\displaystyle C^{\infty }(M)\subset {\mathcal {D}}^{1}(M)}$ to ${\displaystyle C^{\infty }(M)\subset B}$, and is the identity restricted to that subset. In other words, the differential operator of multiplication by a function ${\displaystyle f}$, goes to the operator of multiplication by the function ${\displaystyle f}$.

We now prove some basic results about ${\displaystyle f_{\nabla }}$:

• ${\displaystyle f_{\nabla }}$ is ${\displaystyle \mathbb {R} }$-bilinear: This is obvious.
• For any element ${\displaystyle X+m(g)}$ in ${\displaystyle {\mathcal {D}}^{1}(M)}$ and any ${\displaystyle h\in C^{\infty }(M)}$, we have ${\displaystyle f_{\nabla }(m(g){\dot {(}}X+m(h))(s)=m(g)f_{\nabla }(X+m(h))(s)}$. This essentially follows from the fact that a connection is tensorial in the direction of differentiation:

${\displaystyle f_{\nabla }(m(g){\dot {(}}X+m(h)))(s)=f_{\nabla }(gX+m(gh))(s)=\nabla _{gX}(s)+(gh)(s)=g\nabla _{X}(s)+(gh)(s)=g(\nabla _{X}(s)+hs)}$.

• For any element ${\displaystyle X+m(g)}$ in ${\displaystyle {\mathcal {D}}^{1}(M)}$ and any ${\displaystyle h\in C^{\infty }(M)}$, we have ${\displaystyle f_{\nabla }((X+m(h)){\dot {m}}(g))(s)=f_{\nabla }(X+m(h))(m(g)s)}$. This essentially follows from the Leibniz rule property.

${\displaystyle f_{\nabla }((X+m(h)){\dot {m}}(g))(s)=f_{\nabla }(m(Xg)+g\nabla _{X}+m(gh))(s)=(Xg)(s)+g\nabla _{X}(s)+(gh)s=\nabla _{X}(gs)+(gh)(s)}$.

References

Textbook references

• Book:Globalcalculus^{More info}, Page 64