In mathematics, particularly differential topology, the double tangent bundle or the second tangent bundle refers to the tangent bundle of the total space TM of the tangent bundle of a smooth manifold M.[1] A note on notation: in this article, we denote projection maps by their domains, e.g., πTTM : TTM → TM. Some authors index these maps by their ranges instead, so for them, that map would be written πTM.
The second tangent bundle arises in the study of connections and second order ordinary differential equations, i.e., (semi)spray structures on smooth manifolds, and it is not to be confused with the second order jet bundle.
Since is a vector bundle in its own right, its tangent bundle has the secondary vector bundle structure where is the push-forward of the canonical projection In the following we denote
\xi=
| ||||
| \xi |
|x\inTxM, X=
| ||||
| X |
|x\inTxM
and apply the associated coordinate system
\xi\mapsto(x1,\ldots,xn,\xi1,\ldots,\xin)
on TM. Then the fibre of the secondary vector bundle structure at X∈TxM takes the form
(\piTM
| -1 | |
| ) | |
| *(X) |
=\{
| ||||
| X |
|\xi+
| ||||
| Y |
|\xi | \xi\inTxM , Y1,\ldots,Yn\in\R \}.
The double tangent bundle is a double vector bundle.
The canonical flip[2] is a smooth involution j:TTM→TTM that exchanges these vector space structuresin the sense that it is a vector bundle isomorphism between and In the associated coordinates on TM it reads as
| ||||
| j(X |
|\xi+
| ||||
| Y |
|\xi) =
| ||||
| \xi |
|X+
| ||||
| Y |
|X.
The canonical flip has the property that for any f: R2 → M,
| \partialf | |
| {\partialt |
{\partials}}=j\circ
| \partialf | |
| {\partials |
{\partialt}}
This property can, in fact, be used to give an intrinsic definition of the canonical flip.[3] Indeed, there is a submersionp: J20 (R2,M) → TTM given by
| p([f])= | \partialf |
| {\partialt |
{\partials}}(0,0)
J:
| 2,M) | |
| J | |
| 0(R |
\to
| 2,M) | |
| J | |
| 0(R |
/ J([f])=[f\circ\alpha]
As for any vector bundle, the tangent spaces of the fibres TxM of the tangent bundle can be identified with the fibres TxM themselves. Formally this is achieved through the vertical lift, which is a natural vector space isomorphism defined as
(\operatorname{vl}\xiX)[f]:=
| d | |
| dt |
|t=0f(x,\xi+tX), f\inCinfty(TM).
The vertical lift can also be seen as a natural vector bundle isomorphismfrom the pullback bundle of over onto the vertical tangent bundle
VTM:=\operatorname{Ker}(\piTM)*\subsetTTM.
The vertical lift lets us define the canonical vector field
V:TM\toTTM; V\xi:=\operatorname{vl}\xi\xi,
which is smooth in the slit tangent bundle TM\0. The canonical vector field can be also defined as the infinitesimal generator of the Lie-group action
R x (TM\setminus0)\toTM\setminus0; (t,\xi)\mapstoet\xi.
Unlike the canonical vector field, which can be defined for any vector bundle, the canonical endomorphism
J:TTM\toTTM; J\xiX:=\operatorname{vl}\xi(\piTM)*X, X\inT\xiTM
is special to the tangent bundle. The canonical endomorphism J satisfies
\operatorname{Ran}(J)=\operatorname{Ker}(J)=VTM, lLVJ=-J, [JX,JY]=J[JX,Y]+J[X,JY],
and it is also known as the tangent structure for the following reason. If (E,p,M) is any vector bundlewith the canonical vector field V and a (1,1)-tensor field J that satisfies the properties listed above, with VE in place of VTM, then the vector bundle (E,p,M) is isomorphic to the tangent bundle of the base manifold, and J corresponds to the tangent structure of TM in this isomorphism.
There is also a stronger result of this kind [4] which states that if N is a 2n-dimensional manifold and if there exists a (1,1)-tensor field J on N that satisfies
\operatorname{Ran}(J)=\operatorname{Ker}(J), [JX,JY]=J[JX,Y]+J[X,JY],
then N is diffeomorphic to an open set of the total space of a tangent bundle of some n-dimensional manifold M, and J corresponds to the tangent structure of TM in this diffeomorphism.
In any associated coordinate system on TM the canonical vector field and the canonical endomorphism have the coordinate representations
V=
| ||||
| \xi |
, J=
| ||||
| dx |
.
A Semispray structure on a smooth manifold M is by definition a smooth vector field H on TM \0 such that JH=V. An equivalent definition is that j(H)=H, where j:TTM→TTM is the canonical flip. A semispray H is a spray, if in addition, [''V'',''H'']=H.
Spray and semispray structures are invariant versions of second order ordinary differential equations on M. The difference between spray and semispray structures is that the solution curves of sprays are invariant in positive reparametrizations as point sets on M, whereas solution curves of semisprays typically are not.
The canonical flip makes it possible to define nonlinear covariant derivatives on smooth manifolds as follows. Let
T(TM\setminus0)=H(TM\setminus0) ⊕ V(TM\setminus0)
D:(TM\setminus0) x \Gamma(TM)\toTM; DXY:=(\kappa\circj)(Y*X),
DX(\alphaY+\betaZ)=\alphaDXY+\betaDXZ, \alpha,\beta\inR
DX(fY)=X[f]Y+fDXY, f\inCinfty(M)
Any mapping DX with these properties is called a (nonlinear) covariant derivative[5] on M.The term nonlinear refers to the fact that this kind of covariant derivative DX on is not necessarily linear with respect to the direction X∈TM/0 of the differentiation.
Looking at the local representations one can confirm that the Ehresmann connections on (TM/0,πTM/0,M) and nonlinear covariant derivatives on M are in one-to-one correspondence. Furthermore, if DX is linear in X, then the Ehresmann connection is linear in the secondary vector bundle structure, and DX coincides with its linear covariant derivative.