Alekseevsky D. Shortest and straightest geodesics of an invariant sub-Riemanniasn metric on a flag manifold (abstract): Difference between revisions

Revision as of 14:21, 23 August 2018

Title: Shortest and straightest geodesics of an invariant sub-Riemanniasn metric on a flag manifold

Abstract:
There are different equivalent definitions of geodesics of a Riemannian manifold $(M,g)$ :

According to Euler-Lagrange variational definition, geodesics are extremals of length functional or functional of kinetic energy that is shortest curves, joint two closed points.

According to Hamilton approach, geodesics are projection to $M$ of integral curves of the Hamiltoian flow on $(T^{*}M,\omega _{can})<math>withthequadraticHamiltonian<math>H(p)={\frac {1}{2}}g^{-1}(p,p),\,p\in T^{*}M<math>.*AccordingtoLevi-Civita,geodesicsarestraightestcurves,i.e.curves<math>\gamma (s)$ whose tangent field ${\dot {\gamma }}(s)<math>isparallelwithrespecttoLevi-Civitaconnection.Thesedefinitionsmaybegeneralizedtothesub-Riemannianmanifold<math>(M,D,g)$ where $g$ is a sub-Riemannian metric, defined on a bracket generated distribution $D$ . However , as it was remarked by A.M.Vershik and L.D.Faddeev, variational definition of sub-Riemannian geodesics as "shortest" horisontal curves (used in control theory and many applications) is different from definition of geodesics as straightes curves , used in non-holonomic mechanics. Moreover, they proved that generically shortest geodesics are different from straightes geodesics and indicate examples when these to notions are equivalent.

We recall a Schouten-Wagner description of straightest sub-Riemannian geodesics as geodesics of a partial connection and definition of Wagner curvature tensor of such connection.

Then we classify invariant sub-Riemannian structures $(D,g))$ on flag manifolds (i.e. adjoint orbits of a compact simple Lie group ) and study relations between shortest and strainghest sub-Riemannian geodesics of such sub-Riemannian homogeneous manifold.

Event: Local and Nonlocal Geometry of PDEs and Integrability, 8-12 October 2018, SISSA, Trieste, Italy.
The conference in honor of Joseph Krasil'shchik's 70th birthday.

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 * According to Levi-Civita, geodesics are straightest curves, i.e. curves <math>\gamma(s)</math> whose tangent field <math>\dot{\gamma}(s)<math> is parallel with respect to Levi-Civita connection.
-These definitions may be generalized to the sub-Riemannian manifold <math>(M,D,g)</math> where <math>g<math> is a sub-Riemannian metric, defined on a bracket generated distribution <math>D<math>. However , as it was remarked by A.M.Vershik and L.D.Faddeev, variational definition of sub-Riemannian geodesics as "shortest" horisontal curves (used in control theory and many applications) is different from definition of geodesics as straightes curves , used in non-holonomic mechanics. Moreover, they proved that generically shortest geodesics are different from straightes geodesics and indicate examples when these to notions are equivalent.
+These definitions may be generalized to the sub-Riemannian manifold <math>(M,D,g)</math> where <math>g</math> is a sub-Riemannian metric, defined on a bracket generated distribution <math>D</math>. However , as it was remarked by A.M.Vershik and L.D.Faddeev, variational definition of sub-Riemannian geodesics as "shortest" horisontal curves (used in control theory and many applications) is different from definition of geodesics as straightes curves , used in non-holonomic mechanics. Moreover, they proved that generically shortest geodesics are different from straightes geodesics and indicate examples when these to notions are equivalent.
 We recall a Schouten-Wagner description of straightest sub-Riemannian geodesics as geodesics of a partial connection and definition of Wagner curvature tensor of such connection.

Alekseevsky D. Shortest and straightest geodesics of an invariant sub-Riemanniasn metric on a flag manifold (abstract): Difference between revisions

Revision as of 14:21, 23 August 2018

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