Glossary of Riemannian and metric geometry

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This is a glossary of some terms used in Riemannian geometry and metric geometry — it doesn't cover the terminology of differential topology.

The following articles may also be useful; they either contain specialised vocabulary or provide more detailed expositions of the definitions given below.

• Connection
• Curvature
• Metric space
• Riemannian manifold

See also:

• Glossary of general topology
• Glossary of differential geometry and topology
• List of differential geometry topics

Unless stated otherwise, letters X, Y, Z below denote metric spaces, M, N denote Riemannian manifolds, |xy| or ${\displaystyle |xy|_{X}}$ denotes the distance between points x and y in X. Italic word denotes a self-reference to this glossary.

A caveat: many terms in Riemannian and metric geometry, such as convex function, convex set and others, do not have exactly the same meaning as in general mathematical usage.

Alexandrov space a generalization of Riemannian manifolds with upper, lower or integral curvature bounds (the last one works only in dimension 2)

Almost flat manifold

Arc-wise isometry the same as path isometry.

Autoparallel the same as totally geodesic.^[1]

Barycenter, see center of mass.

bi-Lipschitz map. A map ${\displaystyle f:X\to Y}$ is called bi-Lipschitz if there are positive constants c and C such that for any x and y in X

${\displaystyle c|xy|_{X}\leq |f(x)f(y)|_{Y}\leq C|xy|_{X}}$

Busemann function given a ray, γ : [0, ∞)→X, the Busemann function is defined by

${\displaystyle B_{\gamma }(p)=\lim _{t\to \infty }(|\gamma (t)-p|-t)}$

Cartan–Hadamard theorem is the statement that a connected, simply connected complete Riemannian manifold with non-positive sectional curvature is diffeomorphic to Rⁿ via the exponential map; for metric spaces, the statement that a connected, simply connected complete geodesic metric space with non-positive curvature in the sense of Alexandrov is a (globally) CAT(0) space.

Cartan extended Einstein's General relativity to Einstein–Cartan theory, using Riemannian-Cartan geometry instead of Riemannian geometry. This extension provides affine torsion, which allows for non-symmetric curvature tensors and the incorporation of spin–orbit coupling.

Center of mass. A point ${\textstyle q\in M}$ is called the center of mass^[2] of the points ${\textstyle p_{1},p_{2},\dots ,p_{k}}$ if it is a point of global minimum of the function

${\displaystyle f(x)=\sum _{i}|p_{i}x|^{2}.}$

Such a point is unique if all distances ${\displaystyle |p_{i}p_{j}|}$ are less than the convexity radius.

Christoffel symbol

Collapsing manifold

Complete manifold

Complete metric space

Completion

Conformal map is a map which preserves angles.

Conformally flat a manifold M is conformally flat if it is locally conformally equivalent to a Euclidean space, for example standard sphere is conformally flat.

Conjugate points two points p and q on a geodesic ${\displaystyle \gamma }$ are called conjugate if there is a Jacobi field on ${\displaystyle \gamma }$ which has a zero at p and q.

Convex function. A function f on a Riemannian manifold is a convex if for any geodesic ${\displaystyle \gamma }$ the function ${\displaystyle f\circ \gamma }$ is convex. A function f is called ${\displaystyle \lambda }$-convex if for any geodesic ${\displaystyle \gamma }$ with natural parameter ${\displaystyle t}$, the function ${\displaystyle f\circ \gamma (t)-\lambda t^{2}}$ is convex.

Convex A subset K of a Riemannian manifold M is called convex if for any two points in K there is a unique shortest path connecting them which lies entirely in K, see also totally convex.

Convexity radius at a point ${\textstyle p}$ of a Riemannian manifold is the supremum of radii of balls centered at ${\textstyle p}$ that are (totally) convex. The convexity radius of the manifold is the infimum of the convexity radii at its points; for a compact manifold this is a positive number.^[3] Sometimes the additional requirement is made that the distance function to ${\textstyle p}$ in these balls is convex.^[4]

Cotangent bundle

Covariant derivative

Cut locus

Diameter of a metric space is the supremum of distances between pairs of points.

Developable surface is a surface isometric to the plane.

Dilation same as Lipschitz constant

Exponential map: Exponential map (Lie theory), Exponential map (Riemannian geometry)

Finsler metric

First fundamental form for an embedding or immersion is the pullback of the metric tensor.

Flat manifold

Geodesic is a curve which locally minimizes distance.

Geodesic flow is a flow on a tangent bundle TM of a manifold M, generated by a vector field whose trajectories are of the form ${\displaystyle (\gamma (t),\gamma '(t))}$ where ${\displaystyle \gamma }$ is a geodesic.

Gromov-Hausdorff convergence

Geodesic metric space is a metric space where any two points are the endpoints of a minimizing geodesic.

Hadamard space is a complete simply connected space with nonpositive curvature.

Horosphere a level set of Busemann function.

Injectivity radius The injectivity radius at a point p of a Riemannian manifold is the supremum of radii for which the exponential map at p is a diffeomorphism. The injectivity radius of a Riemannian manifold is the infimum of the injectivity radii at all points.^[5] See also cut locus.

For complete manifolds, if the injectivity radius at p is a finite number r, then either there is a geodesic of length 2r which starts and ends at p or there is a point q conjugate to p (see conjugate point above) and on the distance r from p.^[6] For a closed Riemannian manifold the injectivity radius is either half the minimal length of a closed geodesic or the minimal distance between conjugate points on a geodesic.

Infranilmanifold Given a simply connected nilpotent Lie group N acting on itself by left multiplication and a finite group of automorphisms F of N one can define an action of the semidirect product ${\displaystyle N\rtimes F}$ on N. An orbit space of N by a discrete subgroup of ${\textstyle N\rtimes F}$ which acts freely on N is called an infranilmanifold. An infranilmanifold is finitely covered by a nilmanifold.^[7]

Isometry is a map which preserves distances.

Intrinsic metric

Jacobi field A Jacobi field is a vector field on a geodesic γ which can be obtained on the following way: Take a smooth one parameter family of geodesics ${\displaystyle \gamma _{\tau }}$ with ${\displaystyle \gamma _{0}=\gamma }$, then the Jacobi field is described by

${\displaystyle J(t)=\left.{\frac {\partial \gamma _{\tau }(t)}{\partial \tau }}\right|_{\tau =0}.}$

Jordan curve

Kähler-Einstein metric

Kähler metric

Killing vector field

Length metric the same as intrinsic metric.

Levi-Civita connection is a natural way to differentiate vector fields on Riemannian manifolds.

Lipschitz constant of a map is the infimum of numbers L such that the given map is L-Lipschitz.

Lipschitz convergence the convergence of metric spaces defined by Lipschitz distance.

Lipschitz distance between metric spaces is the infimum of numbers r such that there is a bijective bi-Lipschitz map between these spaces with constants exp(-r), exp(r).^[8]

Lipschitz map

Logarithmic map, or logarithm, is a right inverse of Exponential map.^[9][10]

Mean curvature

Metric ball

Metric tensor

Minimal surface is a submanifold with (vector of) mean curvature zero.

Natural parametrization is the parametrization by length.^[11]

Net. A subset S of a metric space X is called ${\textstyle \epsilon }$-net if for any point in X there is a point in S on the distance ${\textstyle \leq \epsilon }$.^[12] This is distinct from topological nets which generalize limits.

Nilmanifold: An element of the minimal set of manifolds which includes a point, and has the following property: any oriented ${\displaystyle S^{1}}$-bundle over a nilmanifold is a nilmanifold. It also can be defined as a factor of a connected nilpotent Lie group by a lattice.

Normal bundle: associated to an embedding of a manifold M into an ambient Euclidean space ${\textstyle {\mathbb {R} }^{N}}$, the normal bundle is a vector bundle whose fiber at each point p is the orthogonal complement (in ${\textstyle {\mathbb {R} }^{N}}$) of the tangent space ${\textstyle T_{p}M}$.

Nonexpanding map same as short map.

Parallel transport

Path isometry

Polyhedral space a simplicial complex with a metric such that each simplex with induced metric is isometric to a simplex in Euclidean space.

Principal curvature is the maximum and minimum normal curvatures at a point on a surface.

Principal direction is the direction of the principal curvatures.

Proper metric space is a metric space in which every closed ball is compact. Equivalently, if every closed bounded subset is compact. Every proper metric space is complete.^[13]

Pseudo-Riemannian manifold

Quasigeodesic has two meanings; here we give the most common. A map ${\displaystyle f:I\to Y}$ (where ${\displaystyle I\subseteq \mathbb {R} }$ is a subinterval) is called a quasigeodesic if there are constants ${\displaystyle K\geq 1}$ and ${\displaystyle C\geq 0}$ such that for every ${\displaystyle x,y\in I}$

${\displaystyle {1 \over K}d(x,y)-C\leq d(f(x),f(y))\leq Kd(x,y)+C.}$

Note that a quasigeodesic is not necessarily a continuous curve.

Quasi-isometry. A map ${\displaystyle f:X\to Y}$ is called a quasi-isometry if there are constants ${\displaystyle K\geq 1}$ and ${\displaystyle C\geq 0}$ such that

${\displaystyle {1 \over K}d(x,y)-C\leq d(f(x),f(y))\leq Kd(x,y)+C.}$

and every point in Y has distance at most C from some point of f(X). Note that a quasi-isometry is not assumed to be continuous. For example, any map between compact metric spaces is a quasi isometry. If there exists a quasi-isometry from X to Y, then X and Y are said to be quasi-isometric.

Radius of metric space is the infimum of radii of metric balls which contain the space completely.^[14]

Ray is a one side infinite geodesic which is minimizing on each interval.^[15]

Ricci curvature

Riemann

Riemann curvature tensor

Riemannian manifold

Riemannian submersion is a map between Riemannian manifolds which is submersion and submetry at the same time.

Scalar curvature

Second fundamental form is a quadratic form on the tangent space of hypersurface, usually denoted by II, an equivalent way to describe the shape operator of a hypersurface,

${\displaystyle {\text{II}}(v,w)=\langle S(v),w\rangle }$

It can be also generalized to arbitrary codimension, in which case it is a quadratic form with values in the normal space.

Shape operator for a hypersurface M is a linear operator on tangent spaces, S_p: T_pM→T_pM. If n is a unit normal field to M and v is a tangent vector then

${\displaystyle S(v)=\pm \nabla _{v}n}$

(there is no standard agreement whether to use + or − in the definition).

Short map is a distance non increasing map.

Smooth manifold

Sol manifold is a factor of a connected solvable Lie group by a lattice.

Submetry A short map f between metric spaces is called a submetry^[16] if there exists R > 0 such that for any point x and radius r < R the image of metric r-ball is an r-ball, i.e.$${\displaystyle f(B_{r}(x))=B_{r}(f(x)).}$$Sub-Riemannian manifold

Systole. The k-systole of M, ${\textstyle syst_{k}(M)}$, is the minimal volume of k-cycle nonhomologous to zero.

Tangent bundle

Totally convex A subset K of a Riemannian manifold M is called totally convex if for any two points in K any geodesic connecting them lies entirely in K, see also convex.^[17]

Totally geodesic submanifold is a submanifold such that all geodesics in the submanifold are also geodesics of the surrounding manifold.^[18]

Uniquely geodesic metric space is a metric space where any two points are the endpoints of a unique minimizing geodesic.

Word metric on a group is a metric of the Cayley graph constructed using a set of generators.