Projective vector field

Projective vector field

A projective vector field (projective) is a smooth vector field on a semi Riemannian manifold (p.ex. spacetime) M whose flow preserves the geodesic structure of M without necessarily preserving the affine parameter of any geodesic. More intuitively, the flow of the projective maps geodesics smoothly into geodesics without preserving the affine parameter.

Decomposition

In dealing with a vector field X on a semi Riemannian manifold (p.ex. in general relativity), it is often useful to decompose the covariant derivative into its symmetric and skew-symmetric parts:

:X_{a;b}=frac{1}{2}h_{ab}+ F_{ab}

where

:h_{ab}=(mathcal{L}_X g)_{ab}=X_{a;b}+X_{b;a}

and

:F_{ab}=frac{1}{2}(X_{a;b}-X_{b;a})

Note that X_a are the covariant components of X.

Equivalent conditions

Mathematically, the condition for a vector field X to be projective is equivalent to the existence of a one-form psi satisfying

:X_{ab;c}, =R_{abcd}X^d+2g_{a(b}psi_{c)}

which is equivalent to

:h_{ab;c}, =2g_{ab}psi_c+g_{ac}psi_b+g_{bc}psi_a

The set of all global projective vector fields over a connected or compact manifold forms a finite-dimensional Lie algebra denoted by P(M) (the projective algebra) and satisfies for connected manifolds the condition: dim P(M) le n(n+2). Here a projective vector field is uniquely determined by specifying the values of X, abla X and abla abla X (equivalently, specifying X, h, F and psi) at any point of M. (For non-connected manifolds you need to specify these 3 in one point per connected component.) Projectives also satisfy the properties:

:mathcal{L}_X R^a{}_{bcd} = delta ^a{}_d psi_{b;c} - delta ^a{}_c psi_{b;d}:mathcal{L}_X R_{ab}= -3 psi_{a;b}

ubalgebras of the projective algebra

Several important special cases of projective vector fields can occur and they form Lie subalgebras of P(M). These subalgebras are useful, for example, in classifying spacetimes in general relativity.

Affines

Affine vector fields (affines) satisfy abla h=0 (equivalently, psi=0) and hence every affine is a projective. Affines preserve the geodesic structure of the semi Riem. manifold (read spacetime) whilst also preserving the affine parameter. The set of all affines on M forms a Lie subalgebra of P(M) denoted by A(M) (the affine algebra) and satisfies for connected "M", dim A(M) le n(n+1). An affine vector is uniquely determined by specifying the values of the vector field and its first covariant derivative (equivalently, specifying X, h and F) at any point of M. Affines also preserve the Riemann, Ricci and Weyl tensors, i.e.

:mathcal{L}_X R^a{}_{bcd}=0, mathcal{L}_X R_{ab}=0, mathcal{L}_X C^a{}_{bcd}=0

Homotheties

Homothetic vector fields (homotheties) preserve the metric up to a constant factor, i.e. h = mathcal{L}_X g = 2c g. As abla h=0, every homothety is an affine and the set of all homotheties on M forms a Lie subalgebra of A(M) denoted by H(M) (the homothetic algebra) and satisfies for connected "M"

:dim H(M) le frac{1}{2}n(n+1)+1.

A homothetic vector field is uniquely determined by specifying the values of the vector field and its first covariant derivative (equivalently, specifying X, F and c) at any point of the manifold.

Killings

Killing vector fields (Killings) preserve the metric, i.e. h = mathcal{L}_X g = 0. Taking c=0 in the defining property of a homothety, it is seen that every Killing is a homothety (and hence an affine) and the set of all Killing vector fields on M forms a Lie subalgebra of H(M) denoted by K(M) (the Killing algebra) and satisfies for connected "M"

:dim K(M) le frac{1}{2}n(n+1).

A Killing vector field is uniquely determined by specifying the values of the vector field and its first covariant derivative (equivalently, specifying X and F) at any point (for every connected component) of M.

Applications

In general relativity, many spacetimes possess certain symmetries that can be characterised by vector fields on the spacetime. For example, Minkowski space {Bbb M} admits the maximal projective algebra, i.e. dim P({Bbb M}) = 24.

Many other applications of symmetry vector fields in general relativity may be found in Hall (2004) which also contains an extensive bibliography including many research papers in the field of symmetries in general relativity.

References

*
*
*


Wikimedia Foundation. 2010.

Игры ⚽ Поможем сделать НИР

Look at other dictionaries:

  • Vector space — This article is about linear (vector) spaces. For the structure in incidence geometry, see Linear space (geometry). Vector addition and scalar multiplication: a vector v (blue) is added to another vector w (red, upper illustration). Below, w is… …   Wikipedia

  • Vector bundle — The Möbius strip is a line bundle over the 1 sphere S1. Locally around every point in S1, it looks like U × R, but the total bundle is different from S1 × R (which is a cylinder instead). In mathematics, a vector bundle is a… …   Wikipedia

  • Projective space — In mathematics a projective space is a set of elements constructed from a vector space such that a distinct element of the projective space consists of all non zero vectors which are equal up to a multiplication by a non zero scalar. A formal… …   Wikipedia

  • Projective plane — See real projective plane and complex projective plane, for the cases met as manifolds of respective dimension 2 and 4 In mathematics, a projective plane has two possible definitions, one of them coming from linear algebra, and another (which is… …   Wikipedia

  • Projective module — In mathematics, particularly in abstract algebra and homological algebra, the concept of projective module over a ring R is a more flexible generalisation of the idea of a free module (that is, a module with basis vectors). Various equivalent… …   Wikipedia

  • Field with one element — In mathematics, the field with one element is a suggestive name for an object that should exist: many objects in math have properties analogous to objects over a field with q elements, where q = 1, and the analogy between number fields and… …   Wikipedia

  • Projective linear group — In mathematics, especially in area of algebra called group theory, the projective linear group (also known as the projective general linear group) is one of the fundamental groups of study, part of the so called classical groups. The projective… …   Wikipedia

  • Projective line — In mathematics, a projective line is a one dimensional projective space. The projective line over a field K , denoted P1( K ), may be defined as the set of one dimensional subspaces of the two dimensional vector space K 2 (it does carry other… …   Wikipedia

  • Projective frame — In the mathematical field of projective geometry, a projective frame is an ordered collection of points in projective space which can be used as reference points to describe any other point in that space. For example: * Given three distinct… …   Wikipedia

  • Comparison of vector algebra and geometric algebra — Vector algebra and geometric algebra are alternative approaches to providing additional algebraic structures on vector spaces, with geometric interpretations, particularly vector fields in multivariable calculus and applications in mathematical… …   Wikipedia

Share the article and excerpts

Direct link
Do a right-click on the link above
and select “Copy Link”