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In mathematics, a complete manifold (or geodesically complete manifold) $M$ is a (pseudo-) Riemannian manifold for which, starting at any point $p$ , there are straight paths extending infinitely in all directions.

Formally, a manifold $M$ is (geodesically) complete if for any maximal geodesic $\ell :I\to M$ , it holds that $I=(-\infty ,\infty )$ .^[1] A geodesic is maximal if its domain cannot be extended.

Equivalently, $M$ is (geodesically) complete if for all points $p\in M$ , the exponential map at $p$ is defined on $T_{p}M$ , the entire tangent space at $p$ .^[1]

Hopf–Rinow theorem

The Hopf–Rinow theorem gives alternative characterizations of completeness. Let $(M,g)$ be a connected Riemannian manifold and let $d_{g}:M\times M\to [0,\infty )$ be its Riemannian distance function.

The Hopf–Rinow theorem states that $(M,g)$ is (geodesically) complete if and only if it satisfies one of the following equivalent conditions:^[2]

The metric space $(M,d_{g})$ is complete (every $d_{g}$ -Cauchy sequence converges),
All closed and bounded subsets of $M$ are compact.

Examples and non-examples

Euclidean space $\mathbb {R} ^{n}$ , the sphere $\mathbb {S} ^{n}$ , and the tori $\mathbb {T} ^{n}$ (with their natural Riemannian metrics) are all complete manifolds.

All compact Riemannian manifolds and all homogeneous manifolds are geodesically complete. All symmetric spaces are geodesically complete.

Non-examples

A simple example of a non-complete manifold is given by the punctured plane $\mathbb {R} ^{2}\smallsetminus \lbrace 0\rbrace$ (with its induced metric). Geodesics going to the origin cannot be defined on the entire real line. By the Hopf–Rinow theorem, we can alternatively observe that it is not a complete metric space: any sequence in the plane converging to the origin is a non-converging Cauchy sequence in the punctured plane.

There exist non-geodesically complete compact pseudo-Riemannian (but not Riemannian) manifolds. An example of this is the Clifton–Pohl torus.

In the theory of general relativity, which describes gravity in terms of a pseudo-Riemannian geometry, many important examples of geodesically incomplete spaces arise, e.g. non-rotating uncharged black-holes or cosmologies with a Big Bang. The fact that such incompleteness is fairly generic in general relativity is shown in the Penrose–Hawking singularity theorems.

Extendibility

If $M$ is geodesically complete, then it is not isometric to an open proper submanifold of any other Riemannian manifold. The converse does not hold.^[3]

References

Notes

^ ^a ^b Lee 2018, p. 131.
^ do Carmo 1992, p. 146-147.
^ do Carmo 1992, p. 145.

Sources

do Carmo, Manfredo Perdigão (1992), Riemannian geometry, Mathematics: theory and applications, Boston: Birkhäuser, pp. xvi+300, ISBN 0-8176-3490-8

Lee, John (2018). Introduction to Riemannian Manifolds. Graduate Texts in Mathematics. Springer International Publishing AG.

O'Neill, Barrett (1983). Semi-Riemannian Geometry. Academic Press. Chapter 3. ISBN 0-12-526740-1.

[FOOTNOTELee2018131-1] Lee 2018, p. 131.

[FOOTNOTEdo_Carmo1992146-147-2] Carmo 1992, p. 146-147.

[FOOTNOTEdo_Carmo1992145-3] Carmo 1992, p. 145.

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[2]

[3]

@@ Line 1: / Line 1: @@
+{{Short description|Riemannian manifold in which geodesics extend infinitely in all directions}}
-In [[mathematics]], a '''complete manifold''' (or '''geodesically complete manifold''') {{Mvar|M}} is a ([[Pseudo-Riemannian manifold|pseudo]]-) [[Riemannian manifold]] for which, starting at any point {{Math|''p''}}, you can follow a "straight" line indefinitely along any direction. More formally, the [[Exponential map (Riemannian geometry)|exponential map]] at point {{Mvar|p}}, is defined on {{Math|''T''{{sub|''p''}}''M''}}, the entire tangent space at {{Mvar|p}}.
+In [[mathematics]], a '''complete manifold''' (or '''geodesically complete manifold''') {{Mvar|M}} is a ([[Pseudo-Riemannian manifold|pseudo]]-) [[Riemannian manifold]] for which, starting at any point {{Math|''p''}}, there are straight paths extending infinitely in all directions.
-Equivalently, consider a maximal [[geodesic]] <math>\ell\colon I\to M</math>. Here <math>I</math> is an open interval of <math>\mathbb{R}</math>, and, because geodesics are parameterized  with "constant speed", it is uniquely defined up to translation. Because <math>I</math> is maximal, <math>\ell</math> maps the [[End (topology)|ends]] of <math>I</math> to points of {{Math|∂''M''}}, and the length of <math>I</math> measures the distance between those points. A manifold is geodesically complete if for any such geodesic <math>\ell</math>, we have that <math>I=(-\infty,\infty)</math>.
+Formally, a manifold <math>M</math> is (geodesically) complete if for any maximal [[geodesic]] <math>\ell : I \to M</math>, it holds that <math>I=(-\infty,\infty)</math>.{{sfn|Lee|2018|p=131}} A geodesic is '''maximal''' if its domain cannot be extended.
-== Hopf-Rinow theorem ==
-{{Main|Hopf-Rinow theorem}}
+Equivalently, <math>M</math> is (geodesically) complete if for all points <math>p \in M</math>, the [[Exponential map (Riemannian geometry)|exponential map]] at <math>p</math> is defined on <math>T_pM</math>, the entire [[tangent space]] at <math>p</math>.{{sfn|Lee|2018|p=131}}
-The [[Hopf–Rinow theorem]] gives alternative characterizations of completeness. Let <math>(M,g)</math> be a ''connected'' Riemannian manifold and let <math>d_g : M \times M \to [0,\infty)</math> be its [[Riemannian manifold#Metric_space_structure|Riemannian distance function]].
+== Hopf–Rinow theorem ==
-The Hopf–Rinow theorem states that <math>(M,g)</math> is (geodesically) complete if and only if it satisfies one of the following equivalent conditions:
+{{Main|Hopf–Rinow theorem}}
+The [[Hopf–Rinow theorem]] gives alternative characterizations of completeness. Let <math>(M,g)</math> be a ''connected'' Riemannian manifold and let <math>d_g : M \times M \to [0,\infty)</math> be its [[Riemannian manifold#Metric_space_structure|Riemannian distance function]].
-* The metric space <math>(M,d_g)</math> is a [[complete metric space]] (every <math>d_g</math>-[[Cauchy sequence]] converges),
-* A subset of <math>M</math> is compact if and only if it is closed and <math>d_g</math>-bounded.
+The Hopf–Rinow theorem states that <math>(M,g)</math> is (geodesically) complete if and only if it satisfies one of the following equivalent conditions:{{sfn|do Carmo|1992|p=146-147}}
+* The metric space <math>(M,d_g)</math> is [[Complete metric space|complete]] (every <math>d_g</math>-[[Cauchy sequence]] converges),
+* All closed and bounded subsets of <math>M</math> are compact.
 ==Examples and non-examples==
-[[Euclidean space]] <math>\mathbb{R}^n</math>, the [[sphere]]s <math>\mathbb{S}^n</math>, and the [[torus|tori]] <math>\mathbb{T}^n</math> (with their natural [[Riemannian metric]]s) are all complete manifolds.
+[[Euclidean space]] <math>\mathbb{R}^n</math>, the [[n-sphere|sphere]] <math>\mathbb{S}^n</math>, and the [[torus|tori]] <math>\mathbb{T}^n</math> (with their natural [[Riemannian metric]]s) are all complete manifolds.
 All [[compact space|compact]] Riemannian manifolds and all [[homogeneous space|homogeneous]] manifolds are geodesically complete.  All [[symmetric space]]s are geodesically complete.
@@ Line 28: / Line 31: @@
 In the theory of [[general relativity]], which describes gravity in terms of a pseudo-Riemannian geometry, many important examples of geodesically incomplete spaces arise, e.g. [[Schwarzschild metric|non-rotating uncharged black-holes]] or cosmologies with a [[Big Bang]]. The fact that such incompleteness is fairly generic in general relativity is shown in the [[Penrose–Hawking singularity theorems]].
+== Extendibility ==
+If <math>M</math> is geodesically complete, then it is not isometric to an open proper submanifold of any other Riemannian manifold. The converse does not hold.{{sfn|do Carmo|1992|p=145}}
 ==References==
+=== Notes ===
-* {{Cite book|title=Semi-Riemannian Geometry|last=O'Neill|first=Barrett|publisher=[[Academic Press]]|year=1983|isbn=0-12-526740-1|at=Chapter 3}}
+{{reflist}}
+=== Sources ===
+* {{citation
+| last = do Carmo |first=Manfredo Perdigão|authorlink=Manfredo do Carmo
+| title = Riemannian geometry
+| series = Mathematics: theory and applications
+| publisher = Birkhäuser
+| location = Boston
+| year = 1992
+| pages = xvi+300
+| isbn = 0-8176-3490-8
+}}
 * {{Cite book|last=Lee|first=John|title=Introduction to Riemannian Manifolds|series=Graduate Texts in Mathematics|publisher=Springer International Publishing AG|year=2018}}
+* {{Cite book|title=Semi-Riemannian Geometry|last=O'Neill|first=Barrett|publisher=[[Academic Press]]|year=1983|isbn=0-12-526740-1|at=Chapter 3}}
 {{Manifolds}}
+{{Riemannian geometry}}
 {{DEFAULTSORT:Complete Manifold}}

v t e Riemannian geometry (Glossary)
Basic concepts	Curvature tensor Scalar Ricci Sectional Exponential map Geodesic Inner product Metric tensor Levi-Civita connection Covariant derivative Signature Raising and lowering indices/Musical isomorphism Parallel transport Riemannian manifold Pseudo-Riemannian manifold Riemannian volume form
Types of manifolds	Hermitian Hyperbolic Kähler Kenmotsu
Main results	Fundamental theorem of Riemannian geometry Gauss's lemma Gauss–Bonnet theorem Hopf–Rinow theorem Nash embedding theorem Ricci flow Schur's lemma
Generalizations	Finsler Hilbert Sub-Riemannian
Applications	General relativity Geometrization conjecture Poincaré conjecture Uniformization theorem