Connection
on a fibre bundle
A differential-geometric structure on a smooth fibre bundle with a Lie structure group that generalizes connections on a manifold, in particular, for example, the Levi-Civita connection in Riemannian geometry. Let 
be a smooth locally trivial fibration with typical fibre 
on which a Lie group 
acts effectively and smoothly. A connection on this fibre bundle is a mapping of the category of piecewise-smooth curves in the base 
into the category of diffeomorphisms of the fibres that associates with a curve 
(with initial point 
and end point 
) a diffeomorphism 
satisfying the following axioms:
1) for 
, 
, 
, and 
one has
 |
2) for an arbitrary trivializing diffeomorphism 
and for an 
, the diffeomorphism 
, where 
, is defined by the action of some element 
;
3) for an arbitrary piecewise-smooth parametrization 
, the mapping 
, where 
is the image of 
under 
, defines a piecewise-smooth curve in 
that starts from the unit element 
; moreover, 
with a common non-zero tangent vector 
define paths in 
with a common tangent vector 
that depends smoothly on 
and 
.
The diffeomorphism 
is called the parallel displacement along 
. The parallel displacements along all possible closed curves 
form the holonomy group of the connection 
at 
; this group is isomorphic to a Lie subgroup of 
that does not depend on 
. A curve 
on 
is said to be horizontal for 
if 
for any 
and some piecewise-smooth parametrization of it. If 
and 
are given, then there always exists a unique horizontal curve 
, called the horizontal lift of the curve 
, such that 
; it consists of the points 
. The set of horizontal lifts of all curves 
in 
determines the connection 
uniquely: 
maps the end points of all lifted curves of 
into the initial points.
A connection is called linear if 
depends linearly on 
for any 
and 
, or equivalently, if for any 
the tangent vectors of the horizontal curves beginning at 
form a vector subspace 
of 
, called the horizontal subspace. Here 
, where 
is the fibre through 
, that is, 
. The smooth distribution 
is called the horizontal distribution of the linear connection 
. It determines 
uniquely: its integral curves are the horizontal lifts.
A fibre bundle 
is called principal (respectively, a space of homogeneous type), and is denoted by 
(respectively, 
), if 
acts simply transitively (respectively, transitively) on 
, that is, if for any 
there is exactly one (respectively, there is an) element 
that sends 
to 
. Suppose that 
acts on 
from the left; then a natural action from the right is defined on 
, where 
defines 
. Here 
is identified with the quotient manifold 
formed by the orbits 
, where 
is the stationary subgroup of a point from 
. More generally, 
can be identified with the quotient manifold 
of orbits 
relative to the action defined by 
.
A smooth distribution 
on 
is a horizontal distribution of some linear connection (which it determines uniquely) if and only if
 |
for arbitrary 
and 
. All horizontal distributions on 
(respectively, 
) are the images of such 
under the canonical projection 
(respectively, the natural lifts of such 
to 
under the canonical projection 
). Often a linear connection is defined directly as a distribution with the properties mentioned above. It is known that on each 
, and so on every 
and 
, there is a linear connection.
A linear connection in 
is usually studied by using its connection form, which determines it uniquely and can be the basis for another definition. An important characteristic of a linear connection is the curvature form; this can be used to compute the Lie algebra of the holonomy group.
The idea of a connection first arose in 1917 in the work of T. Levi-Civita [1] on parallel displacement of a vector in Riemannian geometry. The notion of an affine connection was introduced by H. Weyl in 1918. In the 1920s E. Cartan (see [3]–[5]) investigated projective and conformal connections (cf. Projective connection; Conformal connection). In 1926 he gave the general concept of a "non-holonomic space with a fundamental group" (see Connections on a manifold), and identified these spaces from the point of view of the general theory of connections. In the 1940s V.V. Vagner developed an even more general concept that is close in spirit (but not in terms of the method) to the modern idea of a connection. 1950 was a decisive year; in it there appeared the survey by Vagner [6], the first notes of G.F. Laptev, which disclosed new approaches, especially analytic ones, and the work of C. Ehresmann [7] that laid the foundation of the modern global theory of connections. See also Weyl connection; Linear connection; Riemannian connection; Symplectic connection; Hermitian connection.
References
| [1] | T. Levi-Civita, "Nozione di parallelismo in una varietà qualunque e consequente specificazione geometrica della curvatura Riemanniana" Rend. Cir. Mat. Palermo , 42 (1917) pp. 173–205 |
| [2] | H. Weyl, "Raum, Zeit, Materie" , Springer (1923) |
| [3] | E. Cartan, "Les espaces à connexion conforme" Ann. Soc. Polon. Math. , 2 (1924) pp. 171–221 |
| [4] | E. Cartan, "Sur les variétés à connexion projective" Bull. Soc. Math. France , 52 (1924) pp. 205–241 |
| [5] | E. Cartan, "Les groupes d'holonomie des espaces généralisés" Acta Math. , 48 (1926) pp. 1–42 |
| [6] | V.V. Vagner, "Theory of a composite manifold" Trudy Sem. Vektor i Tenzor Anal. , 8 (1950) pp. 11–72 (In Russian) |
| [7] | Ch. Ehresmann, "Les connexions infinitésimal dans une espace fibré différentiable" , Colloq. de Topologie Bruxelles, 1950 , G. Thone & Masson (1951) pp. 29–55 |
| [8] | G.F. Laptev, "Differential geometry of imbedded manifolds. Group-theoretical method of differential-geometric investigations" Trudy Moskov. Mat. Obshch. , 2 (1953) pp. 275–382 (In Russian) |
| [9] | K. Nomizu, "Lie groups and differential geometry" , Math. Soc. Japan (1956) |
| [10] | A. Lichnerowicz, "Global theory of connections and holonomy groups" , Noordhoff (1955) (Translated from French) |
| [11] | Ü.G. Lumiste, "Connection theory in bundle spaces" J. Soviet Math. , 1 (1973) pp. 363–390 Itogi Nauk. Ser. Algebra. Topol. Geom. 1969 , 21 (1971) pp. 123–168 |
Comments
Consider a smooth locally trivial fibre bundle 
. A smooth section is a smooth mapping 
such that 
. This concept generalizes that of a function 
(where 
is the fibre of 
), which is the same as a section of the trivial fibre bundle 
. In several areas of mathematics it is important to consider sections instead of just functions. E.g. in gauge field theory. But then one would also like to have something like the partial derivatives of a section available, i.e. the quantity that describes to first order how 
changes as 
varies (infinitesimally). This requires comparing the fibres of 
at neighbouring points, but there is nothing in the concept of a fibre bundle as it stands that allows one to do this. For this some extra structure is needed, and that is provided by the idea of a connection.
It would be simplest if for every two points 
one could prescribe an isomorphism 
in a consistent way, i.e. such that 
for all triples 
. Here 
, the fibre of 
over 
, is of course 
. This, however, would make the bundle trivial, and this is in general not possible. The next best thing would be to have for every smooth path 
from 
to 
an isomorphism 
(which may depend on the path 
) from the fibre at the initial point of the path to the fibre at the final point, subject to certain natural restrictions. This is precisely what a connection is.
There are — at least — three intuitively natural ways of describing a connection.
i) Provide for every smooth path 
from 
to 
an isomorphism 
subject to the three conditions 1), 2), 3).
ii) For each 
let 
be the kernel of the tangent mapping at 
. The subspace 
of the tangent space 
to 
at 
is called the vertical tangent subspace to 
at 
. Now for each 
define a complementary subspace 
at 
, called the horizontal tangent subspace at 
. Thus, 
and 
induces an isomorphism 
. The 
are required to vary smoothly with 
. In the case of linear connections, cf. above, this is the infinitesimal version of i).
iii) Let 
be a vector bundle. Then a linear connection can also be specified by giving so to speak the partial derivatives of a section directly (covariant differentiation). This leads to the specification of a bilinear mapping 
, where 
is the space of vector fields on 
and 
is the space of sections of 
, with certain properties; cf. Linear connection for these properties in the case 
. One consequence of these properties is that 
, 
, 
, depends only on 
at 
. If 
is a smooth path starting in 
with tangent vector 
at 
, then
 |
where 
is parallel displacement defined by 
.
An elegant and convenient way to describe a linear connection in the case that 
is a vector bundle is as follows. Let
 |
be a local chart of 
and a trivialization of 
. Then above 
one has the following local trivialization of 
:
 |
where the right-hand arrow is projection in the first two factors. A linear connection on 
is now given by a bundle mapping 
(i.e. the diagram
 |
is commutative, and 
is linear in the fibres), such that locally the mapping looks like
 |
 |
The 
are the Christoffel symbols (relative to the trivialization 
; in case 
, 
can be taken equal to 
so that the Christoffel symbols depend only on the chart 
).
Given the connection 
, the horizontal subspace 
is defined by
 |
and the covariant derivative of a section 
along a vector field 
is the section 
.
In the case of infinite-dimensional manifolds and bundles this last notion of a linear connection appears to be the appropriate replacement of the more traditional covariant derivative 
, cf. [a2], Sect. 1.1.
References
| [a1] | S. Kobayashi, K. Nomizu, "Foundations of differential geometry" , 1 , Interscience (1963) pp. Chapt. 4 |
| [a2] | W. Klingenberg, "Lectures on closed geodesics" , Springer (1979) |
Connection. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Connection&oldid=46475