Growth conditions, Riemannian completeness and Lorentzian causality

Dirmeier, Alexander; Plaue, Matthias; Scherfner, Mike

doi:10.1016/j.geomphys.2011.04.017

Cited by 11 publications

(13 citation statements)

References 5 publications

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“…As it was observed and actively studied in [4,5,8,10], this Finsler metric and the initial Lorentz metric G are closely related. In particular, for every light-like geodesic γ(τ ) = (t(τ ), x 1 (τ ), x 2 (τ ), x 3 (τ )) of G, its "projection" to S, i.e., the curve τ → (x 1 (τ ), x 2 (τ ), x 3 (τ )) on S is a (probably, reparameterized) geodesic of the Finsler metric (1.6).…”

Section: Statement Of the Problem Motivation And The Main Resultsmentioning

confidence: 68%

Can We Make a Finsler Metric Complete by a Trivial Projective Change?

Matveev

2012

Springer Proceedings in Mathematics &Amp; Statistics

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A trivial projective change of a Finsler metric F is the Finsler metric F + df . I explain when it is possible to make a given Finsler metric both forward and backward complete by a trivial projective change.The problem actually came from lorentz geometry and mathematical relativity: it was observed that it is possible to understand the light-line geodesics of a (normalized, standard) stationary 4-dimensional spacetime as geodesics of a certain Finsler Randers metric on a 3-dimensional manifold. The trivial projective change of the Finsler metric corresponds to the choice of another 3-dimensional slice, and the existence of a trivial projective change that is forward and backward complete is equivalent to the global hyperbolicity of the space-time.

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Section: Statement Of the Problem Motivation And The Main Resultsmentioning

confidence: 68%

Can We Make a Finsler Metric Complete by a Trivial Projective Change?

Matveev

2012

Springer Proceedings in Mathematics &Amp; Statistics

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“…In Theorem 2, F is the norm of the Riemannian metric but, obviously, functional (14) makes sense for any Finsler metric and, under some the conditions as above, its Euler-Lagrange equation can be written as in (14). We say that γ : I ⊂ R → M is a trajectory for the potential V if its restriction to any compact subinterval [a, b] of I is a critical point of the action functional (21). Proof.…”

Section: Notes On the General Finsler Casementioning

confidence: 99%

“…These improvements can be also extended to other contexts, as the completeness of certain Finler metrics in[21].…”

mentioning

confidence: 99%

On the Completeness of Trajectories for Some Mechanical Systems

Sánchez

2015

Geometry, Mechanics, and Dynamics

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The classical tools which ensure the completeness of both, vector fields and second order differential equations for mechanical systems, are revisited. Possible extensions in three directions are discussed: infinite dimensional Banach (and Hilbert) manifolds, Finsler metrics and pseudo-Riemannian spaces, the latter including links with some relativistic spacetimes. Special emphasis is taken in the cleaning up of known techniques, the statement of open questions and the exploration of prospective frameworks.

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“…One of the simplest examples of nonreversible Finsler metrics are Randers metrics, which are defined as the sum of the square root of a Riemannian metric and a one-form having norm less than one at every point. Recently, a relation between Randers metrics and standard stationary spacetimes has been explored [4,7,8,9,10,11,16,19,21,22]. The core of this relation lies in the fact that, as a consequence of the Fermat principle, lightlike geodesics project up to parametrization into geodesics of a Randers metric that we call Fermat metric.…”

Section: Introductionmentioning

confidence: 99%

Almost isometries of non-reversible metrics with applications to stationary spacetimes

Javaloyes

Lichtenfelz

Piccione

2015

Journal of Geometry and Physics

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We develop the basics of a theory of almost isometries for spaces endowed with a quasi-metric. The case of non-reversible Finsler (more specifically, Randers) metrics is of particular interest, and it is studied in more detail. The main motivation arises from General Relativity, and more specifically in spacetimes endowed with a timelike conformal field K, in which case conformal diffeomorphisms correspond to almost isometries of the Fermat metrics defined in the spatial part. A series of results on the topology and the Lie group structure of conformal maps are discussed.

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Growth conditions, Riemannian completeness and Lorentzian causality

Cited by 11 publications

References 5 publications

Can We Make a Finsler Metric Complete by a Trivial Projective Change?

Can We Make a Finsler Metric Complete by a Trivial Projective Change?

On the Completeness of Trajectories for Some Mechanical Systems

Almost isometries of non-reversible metrics with applications to stationary spacetimes

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