Search results for " 28A33"

showing 6 items of 6 documents

Interpolated measures with bounded density in metric spaces satisfying the curvature-dimension conditions of Sturm

2011

We construct geodesics in the Wasserstein space of probability measure along which all the measures have an upper bound on their density that is determined by the densities of the endpoints of the geodesic. Using these geodesics we show that a local Poincar\'e inequality and the measure contraction property follow from the Ricci curvature bounds defined by Sturm. We also show for a large class of convex functionals that a local Poincar\'e inequality is implied by the weak displacement convexity of the functional.

Mathematics - Differential GeometryPure mathematicsGeodesicPoincaré inequalityMetric measure spaceCurvature01 natural sciencesConvexitysymbols.namesakeMathematics - Analysis of PDEsMathematics - Metric GeometryFOS: MathematicsMathematics::Metric Geometry0101 mathematicsRicci curvatureMathematicsProbability measure010102 general mathematicsta111Measure contraction propertyMetric Geometry (math.MG)53C23 (Primary) 28A33 49Q20 (Secondary)Functional Analysis (math.FA)010101 applied mathematicsMathematics - Functional AnalysisMetric spaceRicci curvatureDifferential Geometry (math.DG)Poincaré inequalityBounded functionsymbolsMathematics::Differential GeometryAnalysisAnalysis of PDEs (math.AP)
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Failure of topological rigidity results for the measure contraction property

2014

We give two examples of metric measure spaces satisfying the measure contraction property MCP(K,N) but having different topological dimensions at different regions of the space. The first one satisfies MCP(0,3) and contains a subset isometric to $\mathbb{R}$, but does not topologically split. The second space satisfies MCP(2,3) and has diameter $\pi$, which is the maximal possible diameter for a space satisfying MCP(N-1,N), but is not a topological spherical suspension. The latter example gives an answer to a question by Ohta.

Mathematics - Differential Geometrymetric measure spacesGeodesicPhysics::Instrumentation and DetectorsQuantitative Biology::Tissues and Organsmeasure contraction propertyMetric Geometry (math.MG)53C23 (Primary) 28A33 49Q20 (Secondary)Ricci curvature lower boundsTopologyPotential theorymaximal diameter theoremnonbranchingRigidity (electromagnetism)Mathematics - Metric GeometryDifferential Geometry (math.DG)splitting theoremFOS: MathematicsSplitting theoremContraction (operator theory)AnalysisMathematicsgeodesics
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Dynamics of the scenery flow and geometry of measures

2015

We employ the ergodic theoretic machinery of scenery flows to address classical geometric measure theoretic problems on Euclidean spaces. Our main results include a sharp version of the conical density theorem, which we show to be closely linked to rectifiability. Moreover, we show that the dimension theory of measure-theoretical porosity can be reduced back to its set-theoretic version, that Hausdorff and packing dimensions yield the same maximal dimension for porous and even mean porous measures, and that extremal measures exist and can be chosen to satisfy a generalized notion of self-similarity. These are sharp general formulations of phenomena that had been earlier found to hold in a n…

Pure mathematicsgeometryMatemáticasGeneral MathematicsDimension (graph theory)CONICAL DENSITIESDynamical Systems (math.DS)Measure (mathematics)Matemática Pura//purl.org/becyt/ford/1 [https]RECITFIABILITYEuclidean geometryClassical Analysis and ODEs (math.CA)FOS: MathematicsErgodic theoryscenery flowMathematics - Dynamical SystemsDIMENSIONMathematicsmatematiikkamathematicsta111measures//purl.org/becyt/ford/1.1 [https]Hausdorff spacePOROSITYConical surfacePrimary 28A80 Secondary 37A10 28A75 28A33Flow (mathematics)Mathematics - Classical Analysis and ODEsFRACTAL DISTRIBUTIONSDimension theorygeometriaCIENCIAS NATURALES Y EXACTAS
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Failure of the local-to-global property for CD(K,N) spaces

2016

Given any K and N we show that there exists a compact geodesic metric measure space satisfying locally the CD(0,4) condition but failing CD(K,N) globally. The space with this property is a suitable non convex subset of R^2 equipped with the l^\infty-norm and the Lebesgue measure. Combining many such spaces gives a (non compact) complete geodesic metric measure space satisfying CD(0,4) locally but failing CD(K,N) globally for every K and N.

Mathematics - Differential GeometryDiscrete mathematicsProperty (philosophy)GeodesicLebesgue measureExistential quantification010102 general mathematicsMetric Geometry (math.MG)Space (mathematics)01 natural sciencesMeasure (mathematics)Theoretical Computer ScienceMathematics (miscellaneous)Mathematics - Metric GeometryDifferential Geometry (math.DG)0103 physical sciencesMetric (mathematics)FOS: Mathematics010307 mathematical physics0101 mathematics53C23 (Primary) 28A33 49Q20 (Secondary)MathematicsANNALI SCUOLA NORMALE SUPERIORE - CLASSE DI SCIENZE
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Empirical measures and Vlasov hierarchies

2013

The present note reviews some aspects of the mean field limit for Vlasov type equations with Lipschitz continuous interaction kernel. We discuss in particular the connection between the approach involving the N-particle empirical measure and the formulation based on the BBGKY hierarchy. This leads to a more direct proof of the quantitative estimates on the propagation of chaos obtained on a more general class of interacting systems in [S.Mischler, C. Mouhot, B. Wennberg, arXiv:1101.4727]. Our main result is a stability estimate on the BBGKY hierarchy uniform in the number of particles, which implies a stability estimate in the sense of the Monge-Kantorovich distance with exponent 1 on the i…

MSC 82C05 (35F25 28A33)[PHYS.MPHY]Physics [physics]/Mathematical Physics [math-ph]FOS: Physical sciences01 natural sciencesVlasov type equation Mean-field limit Empirical measure BBGKY hierarchy Monge-Kantorovich distanceMathematics - Analysis of PDEs[MATH.MATH-MP]Mathematics [math]/Mathematical Physics [math-ph]FOS: Mathematics[MATH.MATH-AP]Mathematics [math]/Analysis of PDEs [math.AP]Applied mathematicsMonge-Kantorovich distanceDirect proof0101 mathematicsEmpirical measureMathematical PhysicsMean field limitMathematicsNumerical AnalysisHierarchy010102 general mathematicsVlasov type equationMathematical Physics (math-ph)Empirical measureBBGKY hierarchyLipschitz continuity010101 applied mathematicsKernel (algebra)Uniqueness theorem for Poisson's equationBBGKY hierarchyModeling and SimulationExponent82C05 (35F25 28A33)Analysis of PDEs (math.AP)Kinetic & Related Models
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Structure of distributions generated by the scenery flow

2015

We expand the ergodic theory developed by Furstenberg and Hochman on dynamical systems that are obtained from magnifications of measures. We prove that any fractal distribution in the sense of Hochman is generated by a uniformly scaling measure, which provides a converse to a regularity theorem on the structure of distributions generated by the scenery flow. We further show that the collection of fractal distributions is closed under the weak topology and, moreover, is a Poulsen simplex, that is, extremal points are dense. We apply these to show that a Baire generic measure is as far as possible from being uniformly scaling: at almost all points, it has all fractal distributions as tangent …

Dynamical systems theoryWeak topologyMatemáticasGeneral MathematicsdistributionsDynamical Systems (math.DS)Scenery flowMeasure (mathematics)Matemática PuraFractalPrimary 37A10 28A80 Secondary 28A33 28A75Fractal distributionClassical Analysis and ODEs (math.CA)FOS: MathematicsErgodic theoryscenery flowMathematics - Dynamical SystemsScalingMathematicsCP-processergodic theoryMathematical analysista111Distribution (mathematics)Flow (mathematics)Mathematics - Classical Analysis and ODEsCIENCIAS NATURALES Y EXACTAS
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