Anosov diffeomorphism: Difference between revisions

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			{{Short description\|Diffeomorphism that has a hyperbolic structure on the tangent bundle}}
	In ], more particularly in the fields of ] and ], an '''Anosov map''' on a ] ''M'' is a certain type of mapping, from ''M'' to itself, with rather clearly marked local directions of 'expansion' and 'contraction'.		In ], more particularly in the fields of ] and ], an '''Anosov map''' on a ] ''M'' is a certain type of mapping, from ''M'' to itself, with rather clearly marked local directions of "expansion" and "contraction". Anosov systems are a special case of ] systems.

	'''Anosov diffeomorphisms''' were introduced by ], who proved that their behaviour was in an appropriate sense ''generic'' (when they exist at all).		'''Anosov diffeomorphisms''' were introduced by ], who proved that their behaviour was in an appropriate sense ''generic'' (when they exist at all).<ref>], ''Geodesic flows on closed Riemannian manifolds with negative curvature'', (1967) Proc. Steklov Inst. Mathematics. '''90'''.</ref>

	== Overview ==		== Overview ==
	Three closely related definitions must be distinguished:		Three closely related definitions must be distinguished:
		⚫	* If a differentiable ] ''f'' on ''M'' has a ] on the ], then it is called an '''Anosov map'''. Examples include the ], and ].

⚫	* If a differentiable ] ''f'' on ''M'' has a ] on the ], then it is called an '''Anosov map'''. Examples include the ], and ].

	* If the map is a ], then it is called an '''Anosov diffeomorphism'''.		* If the map is a ], then it is called an '''Anosov diffeomorphism'''.
		⚫	* If a ] on a manifold splits the tangent bundle into three invariant ]s, with one subbundle that is exponentially contracting, and one that is exponentially expanding, and a third, non-expanding, non-contracting one-dimensional sub-bundle (spanned by the flow direction), then the flow is called an '''Anosov flow'''.

			A classical example of Anosov diffeomorphism is the ].
⚫	* If a ] on a manifold splits the tangent bundle into three invariant ]s, with one subbundle that is exponentially contracting, and one that is exponentially expanding, and a third, non-expanding, non-contracting one-dimensional sub-bundle, then the flow is called an '''Anosov flow'''.

	Anosov proved that Anosov diffeomorphisms are ] and form an open subset of mappings (flows) with the ''C''<sup>1</sup> topology.		Anosov proved that Anosov diffeomorphisms are ] and form an open subset of mappings (flows) with the ''C''<sup>1</sup> topology.
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	Not every manifold admits an Anosov diffeomorphism; for example, there are no such diffeomorphisms on the ] . The simplest examples of compact manifolds admitting them are the tori: they admit the so-called '''linear Anosov diffeomorphisms''', which are isomorphisms having no eigenvalue of modulus 1. It was proved that any other Anosov diffeomorphism on a torus is ] to one of this kind.		Not every manifold admits an Anosov diffeomorphism; for example, there are no such diffeomorphisms on the ] . The simplest examples of compact manifolds admitting them are the tori: they admit the so-called '''linear Anosov diffeomorphisms''', which are isomorphisms having no eigenvalue of modulus 1. It was proved that any other Anosov diffeomorphism on a torus is ] to one of this kind.

	The problem of classifying manifolds that admit Anosov diffeomorphisms turned out to be very difficult, and still {{As of\|~~2005~~\|lc=on}} has no answer. The only known examples are ]s, and it is conjectured that they are the only ones.		The problem of classifying manifolds that admit Anosov diffeomorphisms turned out to be very difficult, and still {{As of\|2023\|lc=on}} has no answer for dimension over 3. The only known examples are ]s, and it is conjectured that they are the only ones.

			A sufficient condition for transitivity is that all points are nonwandering: <math> \Omega(f)=M </math>. This in turn holds for codimension-one Anosov diffeomorphisms (i.e., those for which the contracting or the expanding subbundle is one-dimensional)<ref>{{cite journal \|last1=Newhouse \|first1=Sheldon E. \|title=On codimension one Anosov diffeomorphisms \|journal=American Journal of Mathematics \|date=1970 \|volume=92 \|pages=761–770 \|doi=10.2307/2373372 \|url=https://doi.org/10.2307/2373372}}</ref> and for codimension one Anosov flows on manifolds of dimension greater than three<ref>{{cite journal \|last1=Verjovsky \|first1=Alberto \|title=Codimension one Anosov flows \|journal=Boletín de la Sociedad Matemática Mexicana. Segunda Serie \|date=1974 \|volume=19 \|issue=2 \|pages=49–77}}</ref> as well as Anosov flows whose Mather spectrum is contained in two sufficiently thin annuli.<ref>{{cite journal \|last1=Brin \|first1=M. I. \|title=Nonwandering points of Anosov diffeomorphisms \|journal=Astérisque \|date=1977 \|volume=49 \|pages=11–18}}</ref> It is not known whether Anosov diffeomorphisms are transitive (except on infranilmanifolds), but Anosov flows need not be topologically transitive.<ref>{{cite journal \|last1=Béguin \|first1=François \|last2=Bonatti \|first2=Christian \|last3=Yu \|first3=Bin \|title=Building Anosov flows on 3-manifolds \|journal=Geometry & Topology \|date=2017 \|volume=21 \|issue=3 \|pages=1837–1930 \|doi=10.2140/gt.2017.21.1837 \|url=https://doi.org/10.2140/gt.2017.21.1837}}</ref>
	Another famous problem is to determine whether or not the ] of an Anosov diffeomorphism must be the whole manifold. This is known to be true for linear Anosov diffeomorphisms (and hence for any Anosov diffeomorphism in a torus). As of December 2007, it is believed to be proved for all Anosov diffeomorphisms (Xia 2007).

			Also, it is unknown if every <math>C^1</math> volume-preserving Anosov diffeomorphism is ergodic. Anosov proved it under a <math>C^2</math> assumption. It is also true for <math>C^{1+\alpha}</math> volume-preserving Anosov diffeomorphisms.

			For <math>C^2</math> transitive Anosov diffeomorphism <math>f\colon M\to M </math> there exists a unique SRB measure (the acronym stands for Sinai, Ruelle and Bowen) <math> \mu_f </math> supported on <math> M </math> such that its basin <math> B(\mu_f)</math> is of full volume, where

			:<math> B(\mu_f)= \left \{x\in M:\frac{1}{n}\sum_{k=0}^{n-1}\delta_{f^kx}\to\mu_f \right \}. </math>

	==Anosov flow on (tangent bundles of) Riemann surfaces==		==Anosov flow on (tangent bundles of) Riemann surfaces==
	As an example, this section develops the case of the Anosov flow on the ] of a ] of negative ]. This flow can be understood in terms of the flow on the tangent bundle of the ] of hyperbolic geometry. Riemann surfaces of negative curvature may be defined as ]s, that is, as the quotients of the ] and a ]. For the following, let ''H'' be the upper half-plane; let Γ be a Fuchsian group; let ''M''=''H''\Γ be a Riemann surface of negative curvature, and let ~~''T''~~<~~sup~~>1</~~sup~~>~~''M''~~ be the tangent bundle of unit-length vectors on the manifold ''M'', and let ~~''T''~~<~~sup~~>1</~~sup~~>~~''H''~~ be the tangent bundle of unit-length vectors on ''H''. Note that a bundle of unit-length vectors on a surface is a complex ].		As an example, this section develops the case of the Anosov flow on the ] of a ] of negative ]. This flow can be understood in terms of the flow on the tangent bundle of the ] of hyperbolic geometry. Riemann surfaces of negative curvature may be defined as ]s, that is, as the quotients of the ] and a ]. For the following, let ''H'' be the upper half-plane; let Γ be a Fuchsian group; let ''M'' = ''H''/Γ be a Riemann surface of negative curvature as the quotient of "M" by the action of the group Γ, and let <math>T^1 M</math> be the tangent bundle of unit-length vectors on the manifold ''M'', and let <math>T^1 H</math> be the tangent bundle of unit-length vectors on ''H''. Note that a bundle of unit-length vectors on a surface is the ] of a complex ].

	===Lie vector fields===		===Lie vector fields===
	One starts by noting that ~~''T''~~<~~sup~~>1</~~sup~~>~~''H''~~ is isomorphic to the ] ]. This group is the group of orientation-preserving ] of the upper half-plane. The ] of PSL(2,'''R''') is sl(2,'''R'''), and is represented by the matrices		One starts by noting that <math>T^1 H</math> is isomorphic to the ] ]. This group is the group of orientation-preserving ] of the upper half-plane. The ] of PSL(2,'''R''') is sl(2,'''R'''), and is represented by the matrices

			:<math>J=\begin{pmatrix} 1/2 &0\\ 0&-1/2\\ \end{pmatrix} \qquad X=\begin{pmatrix}0&1\\ 0&0\\ \end{pmatrix} \qquad Y=\begin{pmatrix}0&0\\ 1&0 \end{pmatrix}</math>
	:<math>
	J=\left(\begin{matrix} 1/2 &0\\ 0&-1/2\\ \end{matrix}\right) \quad \quad
	X=\left(\begin{matrix}0&1\\ 0&0\\ \end{matrix}\right) \quad \quad
	Y=\left(\begin{matrix}0&0\\ 1&0\\ \end{matrix}\right)
	</math>

	which have the algebra		which have the algebra

	:<math>=X \~~quad\quad~~ = -Y \~~quad\quad~~ = 2J</math>		:<math>=X \qquad = -Y \qquad = 2J</math>

	The ]s		The ]s

			:<math>g_t = \exp(tJ)= \begin{pmatrix}e^{t/2}&0\\ 0&e^{-t/2}\\ \end{pmatrix} \qquad h^*_t = \exp(tX)=\begin{pmatrix}1&t\\ 0&1\\ \end{pmatrix} \qquad h_t = \exp(tY)= \begin{pmatrix}1&0\\ t&1\\ \end{pmatrix}</math>
	:<math>g_t = \exp(tJ)=\left(\begin{matrix}e^{t/2}&0\\
	0&e^{-t/2}\\ \end{matrix}\right) \quad\quad

		⚫	define right-invariant ]s on the manifold of <math>T^1 H = \operatorname{PSL}(2,\R)</math>, and likewise on <math>T^1M</math>. Defining <math>P=T^1H</math> and <math>Q=T^1M</math>, these flows define vector fields on ''P'' and ''Q'', whose vectors lie in ''TP'' and ''TQ''. These are just the standard, ordinary Lie vector fields on the manifold of a Lie group, and the presentation above is a standard exposition of a Lie vector field.
	h^*_t = \exp(tX)=\left(\begin{matrix}1&t\\
	0&1\\ \end{matrix}\right) \quad\quad

	h_t = \exp(tY)=\left(\begin{matrix}1&0\\
	t&1\\ \end{matrix}\right)
	</math>

⚫	define right-invariant ]s on the manifold of ~~''T''~~<~~sup~~>1~~</sup>''~~H''=PSL(2,~~'''~~R~~'''~~), and likewise on ~~''T''~~<~~sup~~>1</~~sup~~>~~''M''~~. Defining ''P''=''T~~''<sup>1~~</~~sup~~>~~''H''~~ and ''Q''=''T~~''<sup>1~~</~~sup~~>~~''M''~~, these flows define vector fields on ''P'' and ''Q'', whose vectors lie in ''TP'' and ''TQ''. These are just the standard, ordinary Lie vector fields on the manifold of a Lie group, and the presentation above is a standard exposition of a Lie vector field.

	===Anosov flow===		===Anosov flow===
	The connection to the Anosov flow comes from the realization that <math>g_t</math> is the ] on ''P'' and ''Q''. Lie vector fields being (by definition) left invariant under the action of a group element, one has that these fields are left invariant under the specific elements <math>g_t</math> of the geodesic flow. In other words, the spaces ''TP'' and ''TQ'' are split into three one-dimensional spaces, or ]s, each of which are invariant under the geodesic flow. The final step is to notice that vector fields in one subbundle expand (and expand exponentially), those in another are unchanged, and those in a third shrink (and do so exponentially).		The connection to the Anosov flow comes from the realization that <math>g_t</math> is the ] on ''P'' and ''Q''. Lie vector fields being (by definition) left invariant under the action of a group element, one has that these fields are left invariant under the specific elements <math>g_t</math> of the geodesic flow. In other words, the spaces ''TP'' and ''TQ'' are split into three one-dimensional spaces, or ]s, each of which are invariant under the geodesic flow. The final step is to notice that vector fields in one subbundle expand (and expand exponentially), those in another are unchanged, and those in a third shrink (and do so exponentially).

	More precisely, the tangent bundle ''TQ'' may be written as the ]		More precisely, the tangent bundle ''TQ'' may be written as the ]

	:<math>TQ = E^+ \oplus E^0 \oplus E^-</math>		:<math>TQ = E^+ \oplus E^0 \oplus E^-</math>
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	:<math>T_qQ = E_q^+ \oplus E_q^0 \oplus E_q^-</math>		:<math>T_qQ = E_q^+ \oplus E_q^0 \oplus E_q^-</math>

	corresponding to the Lie algebra generators ''Y'', ''J'' and ''X'', respectively, carried, by the left action of group element ''g'', from the origin ''e'' to the point ''q''. That is, one has <math>E_e^+=Y~~</math>~~, ~~<math>~~E_e^0=J</math> and <math>E_e^-=X</math>. These spaces are each ]s, and are preserved (are invariant) under the action of the ]; that is, under the action of group elements <math>g=g_t</math>.		corresponding to the Lie algebra generators ''Y'', ''J'' and ''X'', respectively, carried, by the left action of group element ''g'', from the origin ''e'' to the point ''q''. That is, one has <math>E_e^+=Y, E_e^0=J</math> and <math>E_e^-=X</math>. These spaces are each ]s, and are preserved (are invariant) under the action of the ]; that is, under the action of group elements <math>g=g_t</math>.

	To compare the lengths of vectors in <math>T_qQ</math> at different points ''q'', one needs a metric. Any ] at <math>T_eP=sl(2,\~~mathbb{~~R})</math> extends to a left-invariant ] on ''P'', and thus to a Riemannian metric on ''Q''. The length of a vector <math>v \in E^+_q</math> expands exponentially as exp(t) under the action of <math>g_t</math>. The length of a vector <math>v \in E^-_q</math> shrinks exponentially as exp(-t) under the action of <math>g_t</math>. Vectors in <math>E^0_q</math> are unchanged. This may be seen by examining how the group elements commute. The geodesic flow is invariant,		To compare the lengths of vectors in <math>T_qQ</math> at different points ''q'', one needs a metric. Any ] at <math>T_eP=sl(2,\R)</math> extends to a left-invariant ] on ''P'', and thus to a Riemannian metric on ''Q''. The length of a vector <math>v \in E^+_q</math> expands exponentially as exp(t) under the action of <math>g_t</math>. The length of a vector <math>v \in E^-_q</math> shrinks exponentially as exp(-t) under the action of <math>g_t</math>. Vectors in <math>E^0_q</math> are unchanged. This may be seen by examining how the group elements commute. The geodesic flow is invariant,

	:<math>g_sg_t=g_tg_s=g_{s+t} \,</math>		:<math>g_sg_t=g_tg_s=g_{s+t} </math>

	but the other two shrink and expand:		but the other two shrink and expand:

	:<math>g_sh^_t = h^_{t\exp(-s)}g_s</math>		:<math>g_sh^_t = h^_{t\exp(-s)}g_s</math>

	and		and
⚫	:<math>g_sh_t = h_{t\exp(s)}g_s \,</math>

		⚫	:<math>g_sh_t = h_{t\exp(s)}g_s </math>
⚫	where we recall that a tangent vector in <math>E^+_q</math> is given by the ], with respect to ''t'', of the ] <math>h_t</math>, the setting ''t''=0.

		⚫	where we recall that a tangent vector in <math>E^+_q</math> is given by the ], with respect to ''t'', of the ] <math>h_t</math>, the setting <math>t=0</math>.

	===Geometric interpretation of the Anosov flow===		===Geometric interpretation of the Anosov flow===
	When acting on the point ''z''=''i'' of the upper half-plane, <math>g_t</math> corresponds to a ] on the upper half plane, passing through the point ''z''=''i''. The action is the standard ] action of ] on the upper half-plane, so that		When acting on the point <math>z=i</math> of the upper half-plane, <math>g_t</math> corresponds to a ] on the upper half plane, passing through the point <math>z=i</math>. The action is the standard ] action of ] on the upper half-plane, so that

	:<math>g_t \cdot i = ~~\left(~~ \begin{~~matrix~~} \exp(t/2) & 0 \\		:<math>g_t \cdot i = \begin{pmatrix} \exp(t/2) & 0 \\ 0 & \exp(-t/2) \end{pmatrix} \cdot i = i\exp(t) </math>
	0 & \exp(-t/2) \end{matrix} \right) \cdot i = i\exp(t) </math>

	A general geodesic is given by		A general geodesic is given by

	:<math>~~\left(~~ \begin{~~matrix~~} a & b \\		:<math>\begin{pmatrix} a & b \\ c & d \end{pmatrix} \cdot i\exp(t) = \frac{ai\exp(t)+b}{ci\exp(t)+d} </math>
	c & d \end{matrix} \right) \cdot i\exp(t) =
	\frac{ai\exp(t)+b}{ci\exp(t)+d} </math>

	with ''a'', ''b'', ''c'' and ''d'' real, with ''ad-bc=1''. The curves <math>h^*_t</math> and <math>h_t</math> are called ]. Horocycles correspond to the motion of the normal vectors of a ] on the upper half-plane.		with ''a'', ''b'', ''c'' and ''d'' real, with <math>ad-bc=1</math>. The curves <math>h^*_t</math> and <math>h_t</math> are called ''']s'''. Horocycles correspond to the motion of the normal vectors of a ] on the upper half-plane.

	== See also ==		== See also ==
			* ]

⚫	* ]
	* ]		* ]
		⚫	* ]

			==Notes==
	== Further reading ==
			{{reflist}}

			== References ==
	* {{springer\|author= \|title=Y-system,U-system, C-system\|id=Y/y099010}}		* {{springer\|author= \|title=Y-system,U-system, C-system\|id=Y/y099010}}
		⚫	* Anthony Manning, ''Dynamics of geodesic and horocycle flows on surfaces of constant negative curvature'', (1991), appearing as Chapter 3 in ''Ergodic Theory, Symbolic Dynamics and Hyperbolic Spaces'', Tim Bedford, Michael Keane and Caroline Series, Eds. Oxford University Press, Oxford (1991). {{ISBN\|0-19-853390-X}} ''(Provides an expository introduction to the Anosov flow on'' SL(2,'''R''').)
	* D. V. Anosov, ''Geodesic flows on closed Riemannian manifolds with negative curvature'', (1967) Proc. Steklov Inst. Mathematics. '''90'''.
		⚫	*{{PlanetMath attribution\|title=Anosov diffeomorphism\|id=4511}}
⚫	* Anthony Manning, ''Dynamics of geodesic and horocycle flows on surfaces of constant negative curvature'', (1991), appearing as Chapter 3 in ''Ergodic Theory, Symbolic Dynamics and Hyperbolic Spaces'', Tim Bedford, Michael Keane and Caroline Series, Eds. Oxford University Press, Oxford (1991). ISBN 0-19-853390-X ''(Provides an expository introduction to the Anosov flow on SL(2,'''R''').)''
			* ], ''Magnetic flows on a Riemann surface'', Proc. KAIST Math. Workshop (1993), 93–108.
	* {{citation\|first=Zhihong\|last=Xia\|date=2007\|url= http://atlas-conferences.com/cgi-bin/abstract/cavy-46\|title=Homology of invariant foliations and its applications in dynamics}} abstract from International Conference on Topology and its Applications 2007 at Kyoto

			{{Chaos theory}}
⚫	{{~~planetmath~~\|title=Anosov diffeomorphism\|id=4511}}

⚫	]
	]		]
		⚫	]

			]
	]

Latest revision as of 01:06, 21 January 2024

Diffeomorphism that has a hyperbolic structure on the tangent bundle

In mathematics, more particularly in the fields of dynamical systems and geometric topology, an Anosov map on a manifold M is a certain type of mapping, from M to itself, with rather clearly marked local directions of "expansion" and "contraction". Anosov systems are a special case of Axiom A systems.

Anosov diffeomorphisms were introduced by Dmitri Victorovich Anosov, who proved that their behaviour was in an appropriate sense generic (when they exist at all).

Overview

Three closely related definitions must be distinguished:

If a differentiable map f on M has a hyperbolic structure on the tangent bundle, then it is called an Anosov map. Examples include the Bernoulli map, and Arnold's cat map.
If the map is a diffeomorphism, then it is called an Anosov diffeomorphism.
If a flow on a manifold splits the tangent bundle into three invariant subbundles, with one subbundle that is exponentially contracting, and one that is exponentially expanding, and a third, non-expanding, non-contracting one-dimensional sub-bundle (spanned by the flow direction), then the flow is called an Anosov flow.

A classical example of Anosov diffeomorphism is the Arnold's cat map.

Anosov proved that Anosov diffeomorphisms are structurally stable and form an open subset of mappings (flows) with the C topology.

Not every manifold admits an Anosov diffeomorphism; for example, there are no such diffeomorphisms on the sphere . The simplest examples of compact manifolds admitting them are the tori: they admit the so-called linear Anosov diffeomorphisms, which are isomorphisms having no eigenvalue of modulus 1. It was proved that any other Anosov diffeomorphism on a torus is topologically conjugate to one of this kind.

The problem of classifying manifolds that admit Anosov diffeomorphisms turned out to be very difficult, and still as of 2023 has no answer for dimension over 3. The only known examples are infranilmanifolds, and it is conjectured that they are the only ones.

A sufficient condition for transitivity is that all points are nonwandering: $\Omega (f)=M$ . This in turn holds for codimension-one Anosov diffeomorphisms (i.e., those for which the contracting or the expanding subbundle is one-dimensional) and for codimension one Anosov flows on manifolds of dimension greater than three as well as Anosov flows whose Mather spectrum is contained in two sufficiently thin annuli. It is not known whether Anosov diffeomorphisms are transitive (except on infranilmanifolds), but Anosov flows need not be topologically transitive.

Also, it is unknown if every $C^{1}$ volume-preserving Anosov diffeomorphism is ergodic. Anosov proved it under a $C^{2}$ assumption. It is also true for $C^{1+\alpha }$ volume-preserving Anosov diffeomorphisms.

For $C^{2}$ transitive Anosov diffeomorphism $f\colon M\to M$ there exists a unique SRB measure (the acronym stands for Sinai, Ruelle and Bowen) $\mu _{f}$ supported on $M$ such that its basin $B(\mu _{f})$ is of full volume, where

B(\mu _{f})=\left\{x\in M:{\frac {1}{n}}\sum _{k=0}^{n-1}\delta _{f^{k}x}\to \mu _{f}\right\}.

Anosov flow on (tangent bundles of) Riemann surfaces

As an example, this section develops the case of the Anosov flow on the tangent bundle of a Riemann surface of negative curvature. This flow can be understood in terms of the flow on the tangent bundle of the Poincaré half-plane model of hyperbolic geometry. Riemann surfaces of negative curvature may be defined as Fuchsian models, that is, as the quotients of the upper half-plane and a Fuchsian group. For the following, let H be the upper half-plane; let Γ be a Fuchsian group; let M = H/Γ be a Riemann surface of negative curvature as the quotient of "M" by the action of the group Γ, and let $T^{1}M$ be the tangent bundle of unit-length vectors on the manifold M, and let $T^{1}H$ be the tangent bundle of unit-length vectors on H. Note that a bundle of unit-length vectors on a surface is the principal bundle of a complex line bundle.

Lie vector fields

One starts by noting that $T^{1}H$ is isomorphic to the Lie group PSL(2,R). This group is the group of orientation-preserving isometries of the upper half-plane. The Lie algebra of PSL(2,R) is sl(2,R), and is represented by the matrices

J={\begin{pmatrix}1/2&0\\0&-1/2\\\end{pmatrix}}\qquad X={\begin{pmatrix}0&1\\0&0\\\end{pmatrix}}\qquad Y={\begin{pmatrix}0&0\\1&0\end{pmatrix}}

which have the algebra

=X\qquad =-Y\qquad =2J

The exponential maps

g_{t}=\exp(tJ)={\begin{pmatrix}e^{t/2}&0\\0&e^{-t/2}\\\end{pmatrix}}\qquad h_{t}^{*}=\exp(tX)={\begin{pmatrix}1&t\\0&1\\\end{pmatrix}}\qquad h_{t}=\exp(tY)={\begin{pmatrix}1&0\\t&1\\\end{pmatrix}}

define right-invariant flows on the manifold of $T^{1}H=\operatorname {PSL} (2,\mathbb {R} )$ , and likewise on $T^{1}M$ . Defining $P=T^{1}H$ and $Q=T^{1}M$ , these flows define vector fields on P and Q, whose vectors lie in TP and TQ. These are just the standard, ordinary Lie vector fields on the manifold of a Lie group, and the presentation above is a standard exposition of a Lie vector field.

Anosov flow

The connection to the Anosov flow comes from the realization that $g_{t}$ is the geodesic flow on P and Q. Lie vector fields being (by definition) left invariant under the action of a group element, one has that these fields are left invariant under the specific elements $g_{t}$ of the geodesic flow. In other words, the spaces TP and TQ are split into three one-dimensional spaces, or subbundles, each of which are invariant under the geodesic flow. The final step is to notice that vector fields in one subbundle expand (and expand exponentially), those in another are unchanged, and those in a third shrink (and do so exponentially).

More precisely, the tangent bundle TQ may be written as the direct sum

TQ=E^{+}\oplus E^{0}\oplus E^{-}

or, at a point $g\cdot e=q\in Q$ , the direct sum

T_{q}Q=E_{q}^{+}\oplus E_{q}^{0}\oplus E_{q}^{-}

corresponding to the Lie algebra generators Y, J and X, respectively, carried, by the left action of group element g, from the origin e to the point q. That is, one has $E_{e}^{+}=Y,E_{e}^{0}=J$ and $E_{e}^{-}=X$ . These spaces are each subbundles, and are preserved (are invariant) under the action of the geodesic flow; that is, under the action of group elements $g=g_{t}$ .

To compare the lengths of vectors in $T_{q}Q$ at different points q, one needs a metric. Any inner product at $T_{e}P=sl(2,\mathbb {R} )$ extends to a left-invariant Riemannian metric on P, and thus to a Riemannian metric on Q. The length of a vector $v\in E_{q}^{+}$ expands exponentially as exp(t) under the action of $g_{t}$ . The length of a vector $v\in E_{q}^{-}$ shrinks exponentially as exp(-t) under the action of $g_{t}$ . Vectors in $E_{q}^{0}$ are unchanged. This may be seen by examining how the group elements commute. The geodesic flow is invariant,

g_{s}g_{t}=g_{t}g_{s}=g_{s+t}

but the other two shrink and expand:

g_{s}h_{t}^{*}=h_{t\exp(-s)}^{*}g_{s}

and

g_{s}h_{t}=h_{t\exp(s)}g_{s}

where we recall that a tangent vector in $E_{q}^{+}$ is given by the derivative, with respect to t, of the curve $h_{t}$ , the setting $t=0$ .

Geometric interpretation of the Anosov flow

When acting on the point $z=i$ of the upper half-plane, $g_{t}$ corresponds to a geodesic on the upper half plane, passing through the point $z=i$ . The action is the standard Möbius transformation action of SL(2,R) on the upper half-plane, so that

g_{t}\cdot i={\begin{pmatrix}\exp(t/2)&0\\0&\exp(-t/2)\end{pmatrix}}\cdot i=i\exp(t)

A general geodesic is given by

{\begin{pmatrix}a&b\\c&d\end{pmatrix}}\cdot i\exp(t)={\frac {ai\exp(t)+b}{ci\exp(t)+d}}

with a, b, c and d real, with $ad-bc=1$ . The curves $h_{t}^{*}$ and $h_{t}$ are called horocycles. Horocycles correspond to the motion of the normal vectors of a horosphere on the upper half-plane.

Notes

Dmitri V. Anosov, Geodesic flows on closed Riemannian manifolds with negative curvature, (1967) Proc. Steklov Inst. Mathematics. 90.
Newhouse, Sheldon E. (1970). "On codimension one Anosov diffeomorphisms". American Journal of Mathematics. 92: 761–770. doi:10.2307/2373372.
Verjovsky, Alberto (1974). "Codimension one Anosov flows". Boletín de la Sociedad Matemática Mexicana. Segunda Serie. 19 (2): 49–77.
Brin, M. I. (1977). "Nonwandering points of Anosov diffeomorphisms". Astérisque. 49: 11–18.
Béguin, François; Bonatti, Christian; Yu, Bin (2017). "Building Anosov flows on 3-manifolds". Geometry & Topology. 21 (3): 1837–1930. doi:10.2140/gt.2017.21.1837.

References

"Y-system,U-system, C-system", Encyclopedia of Mathematics, EMS Press, 2001
Anthony Manning, Dynamics of geodesic and horocycle flows on surfaces of constant negative curvature, (1991), appearing as Chapter 3 in Ergodic Theory, Symbolic Dynamics and Hyperbolic Spaces, Tim Bedford, Michael Keane and Caroline Series, Eds. Oxford University Press, Oxford (1991). ISBN 0-19-853390-X (Provides an expository introduction to the Anosov flow on SL(2,R).)
This article incorporates material from Anosov diffeomorphism on PlanetMath, which is licensed under the Creative Commons Attribution/Share-Alike License.
Toshikazu Sunada, Magnetic flows on a Riemann surface, Proc. KAIST Math. Workshop (1993), 93–108.

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