Search results for "53C22"

showing 7 items of 7 documents

Counting common perpendicular arcs in negative curvature

2013

Let $D^-$ and $D^+$ be properly immersed closed locally convex subsets of a Riemannian manifold with pinched negative sectional curvature. Using mixing properties of the geodesic flow, we give an asymptotic formula as $t\to+\infty$ for the number of common perpendiculars of length at most $t$ from $D^-$ to $D^+$, counted with multiplicities, and we prove the equidistribution in the outer and inner unit normal bundles of $D^-$ and $D^+$ of the tangent vectors at the endpoints of the common perpendiculars. When the manifold is compact with exponential decay of correlations or arithmetic with finite volume, we give an error term for the asymptotic. As an application, we give an asymptotic form…

Mathematics - Differential GeometryGeneral Mathematics[MATH.MATH-DS]Mathematics [math]/Dynamical Systems [math.DS]37D40 37A25 53C22 30F4001 natural sciencesDomain (mathematical analysis)Bowen-Margulis measurecommon perpendicularequidistributiondecay of correlation0502 economics and businessortholength spectrummixingAsymptotic formulaSectional curvatureTangent vectorMathematics - Dynamical Systems0101 mathematicsExponential decayskinning measurelaskeminenMathematicsconvexityApplied Mathematicsta111010102 general mathematics05 social sciencesMathematical analysisRegular polygonnegative curvatureRiemannian manifoldGibbs measureManifoldKleinian groups[MATH.MATH-DG]Mathematics [math]/Differential Geometry [math.DG]countingMathematics::Differential Geometrygeodesic arc050203 business & management

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Counting and equidistribution in Heisenberg groups

2014

We strongly develop the relationship between complex hyperbolic geometry and arithmetic counting or equidistribution applications, that arises from the action of arithmetic groups on complex hyperbolic spaces, especially in dimension $2$. We prove a Mertens' formula for the integer points over a quadratic imaginary number fields $K$ in the light cone of Hermitian forms, as well as an equidistribution theorem of the set of rational points over $K$ in Heisenberg groups. We give a counting formula for the cubic points over $K$ in the complex projective plane whose Galois conjugates are orthogonal and isotropic for a given Hermitian form over $K$, and a counting and equidistribution result for …

Mathematics - Differential GeometryPure mathematicsGeneral MathematicsHyperbolic geometryMathematics::Number Theory[MATH.MATH-DS]Mathematics [math]/Dynamical Systems [math.DS]11E39 11F06 11N45 20G20 53C17 53C22 53C55chainEquidistribution theorem01 natural sciencesHeisenberg groupequidistributioncommon perpendicularIntegerLight cone0103 physical sciencesHeisenberg groupcubic point0101 mathematicsCygan distanceMertens formulaComplex projective planeMathematicsDiscrete mathematicsAMS codes: 11E39 11F06 11N45 20G20 53C17 53C22 53C55Mathematics - Number TheorySesquilinear formHeisenberg groups010102 general mathematicsHermitian matrixcomplex hyperbolic geometry[MATH.MATH-NT]Mathematics [math]/Number Theory [math.NT]sub-Riemannian geometry[MATH.MATH-DG]Mathematics [math]/Differential Geometry [math.DG]counting010307 mathematical physics

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Tensor tomography on Cartan–Hadamard manifolds

2017

We study the geodesic X-ray transform on Cartan-Hadamard manifolds, and prove solenoidal injectivity of this transform acting on functions and tensor fields of any order. The functions are assumed to be exponentially decaying if the sectional curvature is bounded, and polynomially decaying if the sectional curvature decays at infinity. This work extends the results of Lehtonen (2016) to dimensions $n \geq 3$ and to the case of tensor fields of any order.

Mathematics - Differential GeometryPure mathematicsGeodesic01 natural sciencesTheoretical Computer ScienceTensor fieldHadamard transform44A12 53C21 53C22 45Q05Euclidean geometryFOS: MathematicsSectional curvatureTensor0101 mathematicsMathematical PhysicsMathematicsCartan-Hadamard manifoldsSolenoidal vector fieldApplied Mathematics010102 general mathematicsComputer Science Applications010101 applied mathematicsDifferential Geometry (math.DG)Bounded functionSignal Processingtensor tomographyMathematics::Differential GeometryInverse Problems

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Counting and equidistribution in quaternionic Heisenberg groups

2020

AbstractWe develop the relationship between quaternionic hyperbolic geometry and arithmetic counting or equidistribution applications, that arises from the action of arithmetic groups on quaternionic hyperbolic spaces, especially in dimension 2. We prove a Mertens counting formula for the rational points over a definite quaternion algebra A over ${\mathbb{Q}}$ in the light cone of quaternionic Hermitian forms, as well as a Neville equidistribution theorem of the set of rational points over A in quaternionic Heisenberg groups.

Mathematics - Differential GeometryPure mathematicsMathematics::Dynamical SystemsGeneral MathematicsHyperbolic geometryMathematics::Number Theory[MATH.MATH-DS]Mathematics [math]/Dynamical Systems [math.DS]Dimension (graph theory)11E39 11F06 11N45 20G20 53C17 53C22 53C55[MATH.MATH-DS] Mathematics [math]/Dynamical Systems [math.DS]Equidistribution theorem01 natural sciences[MATH.MATH-GR]Mathematics [math]/Group Theory [math.GR]differentiaaligeometriaSet (abstract data type)Light cone0103 physical sciences0101 mathematics[MATH.MATH-GR] Mathematics [math]/Group Theory [math.GR]MathematicslukuteoriaQuaternion algebraMathematics - Number Theory010102 general mathematicsryhmäteoriaHermitian matrix[MATH.MATH-NT]Mathematics [math]/Number Theory [math.NT]Action (physics)010307 mathematical physicsMathematics::Differential Geometry[MATH.MATH-NT] Mathematics [math]/Number Theory [math.NT]

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Prescribing the behaviour of geodesics in negative curvature

2010

Given a family of (almost) disjoint strictly convex subsets of a complete negatively curved Riemannian manifold M, such as balls, horoballs, tubular neighborhoods of totally geodesic submanifolds, etc, the aim of this paper is to construct geodesic rays or lines in M which have exactly once an exactly prescribed (big enough) penetration in one of them, and otherwise avoid (or do not enter too much in) them. Several applications are given, including a definite improvement of the unclouding problem of [PP1], the prescription of heights of geodesic lines in a finite volume such M, or of spiraling times around a closed geodesic in a closed such M. We also prove that the Hall ray phenomenon desc…

Mathematics - Differential GeometryhoroballsPure mathematicsGeodesicDisjoint setsLagrange spectrum52A5501 natural sciences53C22Mathematics - Metric Geometry0103 physical sciences0101 mathematicshoroball[MATH.MATH-MG]Mathematics [math]/Metric Geometry [math.MG]MathematicsFinite volume methodHall rayAMS : 53 C 22 11 J 06 52 A 55 53 D 25Mathematics - Number Theory010102 general mathematicsnegative curvatureRiemannian manifold[MATH.MATH-NT]Mathematics [math]/Number Theory [math.NT]Closed geodesic53D25[MATH.MATH-DG]Mathematics [math]/Differential Geometry [math.DG]Totally geodesic010307 mathematical physicsGeometry and TopologyNegative curvatureMathematics::Differential GeometryConvex functiongeodesicgeodesics11J06

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Pestov identities and X-ray tomography on manifolds of low regularity

2021

We prove that the geodesic X-ray transform is injective on scalar functions and (solenoidally) on one-forms on simple Riemannian manifolds $(M,g)$ with $g \in C^{1,1}$. In addition to a proof, we produce a redefinition of simplicity that is compatible with rough geometry. This $C^{1,1}$-regularity is optimal on the H\"older scale. The bulk of the article is devoted to setting up a calculus of differential and curvature operators on the unit sphere bundle atop this non-smooth structure.

Mathematics - Differential Geometrynon-smooth geometrygeodesic X-ray tomographyinverse problems44A12 53C22 53C65 58J32Pestov identityinversio-ongelmatdifferentiaaligeometriaRiemannin monistotMathematics - Analysis of PDEsDifferential Geometry (math.DG)tomografiaintegraalilaskentaFOS: MathematicsMathematics::Differential Geometryintegral geometryAnalysis of PDEs (math.AP)

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THE 1-HARMONIC FLOW WITH VALUES IN A HYPEROCTANT OF THE N-SPHERE

2014

We prove the existence of solutions to the 1-harmonic flow — that is, the formal gradient flow of the total variation of a vector field with respect to the [math] -distance — from a domain of [math] into a hyperoctant of the [math] -dimensional unit sphere, [math] , under homogeneous Neumann boundary conditions. In particular, we characterize the lower-order term appearing in the Euler–Lagrange formulation in terms of the “geodesic representative” of a BV-director field on its jump set. Such characterization relies on a lower semicontinuity argument which leads to a nontrivial and nonconvex minimization problem: to find a shortest path between two points on [math] with respect to a metric w…

Unit spherenonconvex variational problemsriemannian manifolds with boundaryGeodesicn-sphereharmonic flows68U1053C2253C4435K9235K67Neumann boundary conditionpartial differential equations49J45MathematicsNumerical Analysisnonlinear parabolic systems; lower semicontinuity and relaxation; total variation flow; 1-harmonic flow; image processing; harmonic flows; partial differential equations; image processing.; geodesics; riemannian manifolds with boundary; nonconvex variational problemslower semicontinuity and relaxation58E20Applied MathematicsMathematical analysis49Q201-harmonic flowimage processingFlow (mathematics)35K55Metric (mathematics)total variation flowVector fieldnonlinear parabolic systemsBalanced flowAnalysisgeodesics

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