Riemannian Bundle Metric
   HOME

TheInfoList



OR:

In
differential geometry Differential geometry is a mathematical discipline that studies the geometry of smooth shapes and smooth spaces, otherwise known as smooth manifolds. It uses the techniques of differential calculus, integral calculus, linear algebra and multili ...
, the notion of a
metric tensor In the mathematical field of differential geometry, a metric tensor (or simply metric) is an additional structure on a manifold (such as a surface) that allows defining distances and angles, just as the inner product on a Euclidean space allows ...
can be extended to an arbitrary
vector bundle In mathematics, a vector bundle is a topological construction that makes precise the idea of a family of vector spaces parameterized by another space X (for example X could be a topological space, a manifold, or an algebraic variety): to every po ...
, and to some
principal fiber bundle In mathematics, a principal bundle is a mathematical object that formalizes some of the essential features of the Cartesian product X \times G of a space X with a group G. In the same way as with the Cartesian product, a principal bundle P is equ ...
s. This metric is often called a bundle metric, or fibre metric.


Definition

If ''M'' is a topological manifold and : ''E'' → ''M'' a vector bundle on ''M'', then a metric on ''E'' is a bundle map ''k'' : ''E'' ×''M'' ''E'' → ''M'' × R from the fiber product of ''E'' with itself to the trivial bundle with fiber R such that the restriction of ''k'' to each fibre over ''M'' is a
nondegenerate In mathematics, a degenerate case is a limiting case of a class of objects which appears to be qualitatively different from (and usually simpler than) the rest of the class, and the term degeneracy is the condition of being a degenerate case. T ...
bilinear map of vector spaces.. Roughly speaking, ''k'' gives a kind of dot product (not necessarily symmetric or positive definite) on the vector space above each point of ''M'', and these products vary smoothly over ''M''.


Properties

Every vector bundle with paracompact base space can be equipped with a bundle metric. For a vector bundle of rank ''n'', this follows from the bundle charts \phi:\pi^(U)\to U\times\mathbb^n: the bundle metric can be taken as the pullback of the
inner product In mathematics, an inner product space (or, rarely, a Hausdorff space, Hausdorff pre-Hilbert space) is a real vector space or a complex vector space with an operation (mathematics), operation called an inner product. The inner product of two ve ...
of a metric on \mathbb^n; for example, the orthonormal charts of Euclidean space. The
structure group In mathematics, and particularly topology, a fiber bundle (or, in Commonwealth English: fibre bundle) is a space that is a product space, but may have a different topological structure. Specifically, the similarity between a space E and a ...
of such a metric is the
orthogonal group In mathematics, the orthogonal group in dimension , denoted , is the Group (mathematics), group of isometry, distance-preserving transformations of a Euclidean space of dimension that preserve a fixed point, where the group operation is given by ...
''O''(''n'').


Example: Riemann metric

If ''M'' is a
Riemannian manifold In differential geometry, a Riemannian manifold or Riemannian space , so called after the German mathematician Bernhard Riemann, is a real manifold, real, smooth manifold ''M'' equipped with a positive-definite Inner product space, inner product ...
, and ''E'' is its tangent bundle T''M'', then the Riemannian metric gives a bundle metric, and vice versa.


Example: on vertical bundles

If the bundle :''P'' → ''M'' is a
principal fiber bundle In mathematics, a principal bundle is a mathematical object that formalizes some of the essential features of the Cartesian product X \times G of a space X with a group G. In the same way as with the Cartesian product, a principal bundle P is equ ...
with group ''G'', and ''G'' is a compact Lie group, then there exists an Ad(''G'')-invariant inner product ''k'' on the fibers, taken from the inner product on the corresponding
compact Lie algebra In the mathematical field of Lie theory, there are two definitions of a compact Lie algebra. Extrinsically and topologically, a compact Lie algebra is the Lie algebra of a compact Lie group; this definition includes tori. Intrinsically and algeb ...
. More precisely, there is a
metric tensor In the mathematical field of differential geometry, a metric tensor (or simply metric) is an additional structure on a manifold (such as a surface) that allows defining distances and angles, just as the inner product on a Euclidean space allows ...
''k'' defined on the vertical bundle E = V''P'' such that ''k'' is invariant under left-multiplication: :k(L_X, L_Y)=k(X,Y) for vertical vectors ''X'', ''Y'' and ''L''''g'' is left-multiplication by ''g'' along the fiber, and ''L''''g*'' is the
pushforward The notion of pushforward in mathematics is "dual" to the notion of pullback, and can mean a number of different but closely related things. * Pushforward (differential), the differential of a smooth map between manifolds, and the "pushforward" op ...
. That is, ''E'' is the vector bundle that consists of the vertical subspace of the tangent of the principal bundle. More generally, whenever one has a compact group with
Haar measure In mathematical analysis, the Haar measure assigns an "invariant volume" to subsets of locally compact topological groups, consequently defining an integral for functions on those groups. This measure was introduced by Alfréd Haar in 1933, though ...
μ, and an arbitrary
inner product In mathematics, an inner product space (or, rarely, a Hausdorff space, Hausdorff pre-Hilbert space) is a real vector space or a complex vector space with an operation (mathematics), operation called an inner product. The inner product of two ve ...
''h(X,Y)'' defined at the tangent space of some point in ''G'', one can define an invariant metric simply by averaging over the entire group, i.e. by defining :k(X,Y)=\int_G h(L_ X, L_ Y) d\mu_g as the average. The above notion can be extended to the associated bundle P\times_G V where ''V'' is a vector space transforming covariantly under some
representation Representation may refer to: Law and politics *Representation (politics), political activities undertaken by elected representatives, as well as other theories ** Representative democracy, type of democracy in which elected officials represent a ...
of ''G''.


In relation to Kaluza–Klein theory

If the base space ''M'' is also a
metric space In mathematics, a metric space is a set together with a notion of ''distance'' between its elements, usually called points. The distance is measured by a function called a metric or distance function. Metric spaces are the most general settin ...
, with metric ''g'', and the principal bundle is endowed with a connection form ω, then *g+kω is a metric defined on the entire tangent bundle ''E'' = T''P''.David Bleecker,
Gauge Theory and Variational Principles
(1982) D. Reidel Publishing ''(See chapter 9'')
More precisely, one writes *g(''X'',''Y'') = ''g''(*''X'', *''Y'') where * is the
pushforward The notion of pushforward in mathematics is "dual" to the notion of pullback, and can mean a number of different but closely related things. * Pushforward (differential), the differential of a smooth map between manifolds, and the "pushforward" op ...
of the projection , and ''g'' is the
metric tensor In the mathematical field of differential geometry, a metric tensor (or simply metric) is an additional structure on a manifold (such as a surface) that allows defining distances and angles, just as the inner product on a Euclidean space allows ...
on the base space ''M''. The expression ''kω'' should be understood as (''kω'')(''X'',''Y'') = ''k''(''ω''(''X''),''ω''(''Y'')), with ''k'' the metric tensor on each fiber. Here, ''X'' and ''Y'' are elements of the tangent space T''P''. Observe that the lift *g vanishes on the
vertical subspace In mathematics, the vertical bundle and the horizontal bundle are vector bundles associated to a smooth fiber bundle. More precisely, given a smooth fiber bundle \pi\colon E\to B, the vertical bundle VE and horizontal bundle HE are subbundles of ...
T''V'' (since * vanishes on vertical vectors), while kω vanishes on the horizontal subspace T''H'' (since the horizontal subspace is defined as that part of the tangent space T''P'' on which the connection ω vanishes). Since the total tangent space of the bundle is a direct sum of the vertical and horizontal subspaces (that is, T''P'' = T''V'' ⊕ T''H''), this metric is well-defined on the entire bundle. This bundle metric underpins the generalized form of Kaluza–Klein theory due to several interesting properties that it possesses. The
scalar curvature In the mathematical field of Riemannian geometry, the scalar curvature (or the Ricci scalar) is a measure of the curvature of a Riemannian manifold. To each point on a Riemannian manifold, it assigns a single real number determined by the geometry ...
derived from this metric is constant on each fiber, this follows from the Ad(''G'') invariance of the fiber metric ''k''. The scalar curvature on the bundle can be decomposed into three distinct pieces: :''R''''E'' = ''R''M(''g'') + ''L''(''g'', ω) + ''R''''G''(''k'') where ''R''''E'' is the scalar curvature on the bundle as a whole (obtained from the metric *g+kω above), and ''R''M(''g'') is the scalar curvature on the base manifold ''M'' (the Lagrangian density of the
Einstein–Hilbert action The Einstein–Hilbert action (also referred to as Hilbert action) in general relativity is the action that yields the Einstein field equations through the stationary-action principle. With the metric signature, the gravitational part of the act ...
), and ''L''(''g'', ω) is the Lagrangian density for the Yang–Mills action, and ''R''''G''(''k'') is the scalar curvature on each fibre (obtained from the fiber metric ''k'', and constant, due to the Ad(''G'')-invariance of the metric ''k''). The arguments denote that ''R''M(''g'') only depends on the metric ''g'' on the base manifold, but not ω or ''k'', and likewise, that ''R''''G''(''k'') only depends on ''k'', and not on ''g'' or ω, and so-on.


References

{{reflist Differential geometry