Dynamics of foliations
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(resp., of $t\in\mathcal{T}$) is denoted by $[(t_j)]$ (resp., by $[t]$). Also, | (resp., of $t\in\mathcal{T}$) is denoted by $[(t_j)]$ (resp., by $[t]$). Also, | ||
we let $\mathcal{E} = \{ [t];\, t\in\mathcal{T}\}$. $\mathcal{E}$ is the set of growth | we let $\mathcal{E} = \{ [t];\, t\in\mathcal{T}\}$. $\mathcal{E}$ is the set of growth | ||
− | types of monotone functions (in the sense of \cite{ | + | types of monotone functions (in the sense of \cite{Hector&Hirsch1981}). The preorder |
$\preceq$ induces a partial order (denoted again by $\preceq$) in | $\preceq$ induces a partial order (denoted again by $\preceq$) in | ||
$\hat{\mathcal{E}}$. | $\hat{\mathcal{E}}$. |
Revision as of 13:20, 27 November 2010
The user responsible for this page is Pawel Walczak. No other user may edit this page at present. |
This page has not been refereed. The information given here might be incomplete or provisional. |
Contents |
1 Introduction
Foliations of Riemannian manifolds can be considered as multidimensional dynamical systems: Riemannian structure (more precisely, Riemannian structure along the leaves) plays the role of time, the leaves play the role of orbits [Walczak2004]. The dynamics of a foliation can be described in terms of its holonomy (see Foliations#Holonomy) pseudogroup. As far as we know, the notion of a pseudogroup appeared for the first time in [Veblen&Whitehead1932] in the context of geometric objects studied in differential geometry. Pseudogroups have been brought into the foliation theory by Haefliger [Haefliger1962a]. The growth types of leaves (equivalent to the growth types of the corresponding orbits of holonomy pseudogroups) as well as the expansion growth of a foliation (or, its holonomy pseudogroup) describe some aspects of the foliation dynamics. Corresponding to the expansion growth is the notion of geometric entropy of a foliation [Ghys&Langevin&Walczak1988]. Vanishing entropy can be seen as a dynamical condition which occurs to have strong geometric and topological consequences (see Dynamics of foliations#Results on entropy) below.
2 Pseudogroups
The notion of a pseudogroup generalizes that of a group of transformations. Given a space , any group of transformations of consists of maps defined globally on , mapping bijectively onto itself and such that the composition of any two of them as well as the inverse of any of them belongs to the group. The same holds for a pseudogroup with this difference that the maps are not defined globally but on open subsets, so the domain of the composition is usually smaller than those of the maps being composed.
To make the above precise, let us take a topological space and denote by Homeo the family of all homeomorphisms between open subsets of . If Homeo, then is its domain and .
Definition 2.1. A subfamily of Homeo is said to be a pseudogroup if it is closed under composition, inversion, restriction to open subdomains and unions. More precisely, should satisfy the following conditions:
(i) whenever and ,
(ii) whenever ,
(iii) whenever and is open,
(iv) if Homeo, is an open cover of and for any , then .
Moreover, we shall always assume that
(v] id (or, equivalently, ).
As examples, one may have (1) all the homeomorphisms between open sets of a topological space, (2) all the diffeomorhisms of a given class (say, , , between open sets of a manifold, (3) all the restrictions to open domains of elements of a given group of homeomorphisms of a given topological space. (In the last case, we say that the pseudogroup is generated by .) Any set of homeomorphisms bewteen open sets (with domains covering a space ) generates ma pseudogroup which is the smallest pseudogroup containing ; precisely a homeomorphism belongs to if and only if for any point there exist elements , exponents and a neighbourhood of such that on . If is finite, is said to be finitely generated.
3 Holonomy pesudogroups
Definition 3.1. A foliated atlas on a foliated manifold is said to be nice (also, nice is the covering of by the domains of the charts ) if
(i) the covering is locally finite,
(ii) for any , is an open cube,
(iii) if and , and , then there exists a foliated chart chart and such that is an open cube, contains the closure of and .
Since manifolds are supposed to be paracompact here, they are separable and hence nice coverings are denumerable. Nice coverings on compact manifolds are finite. On arbitrary foliated manfiolds, nice coverings do exist.
Given a nice covering of a foliated manifold . For any , let be the space of the plaques (i.e., connected components of intersections . being a leaf of ) of contained in . Equip with the quotient topology: two points of are equivalent iff they belong to the same plaque. is homeomorphic (-diffeomorphic when is -differentiable and ) to an open cube () via the map , where is a foliated chart on . The disjoint union
is called a complete transversal for . Transversality refers to the fact that, if is differentiable of class , , each of the spaces can be mapped homeomorphically onto a -submanifold transverse to : if and is the leaf of passing through , then
Completeness of means that every leaf of intersects at least one of the submanifolds .
Definition 3.2. Given a nice covering of a foliated manifold and two sets and such that the holonomy map , being the open subset of which consists of all the plaques of for which , is defined in the following way:
All the maps () generate a pseudogroup on . is called the holonomy pseudogroup of .
This means that any element of assigns to a plaque the end plaque of a chain (that is a sequence of plaques such that any two consequtive plaques intersect) which oroginates at .
Certainly, holonomy pseudogroups of arbitrary compact foliated manifolds are finitely generated. For example, gluing together two 2-dimensional Reeb foliations (see Foliations#Reeb Foliations) on one gets a foliation of the 3-dimensional sphere for which any arc intersecting the unique toral leaf is a complete transversal; can be identified with a segment (), the point of intersection with the number , while the holonomy group with the one on our segment generated by two maps such that , , snd contract their domains towards .
4 Growth
Let us begin with two non-decreasing sequences and of non-negative numbers. We shall say that "grows slower" that () whenever there exist positive constants and such that the inequalities
hold for all . We say that types of growth of our sequences and are the same whenever
Let now be the set of non-negative increasing functions defined on :
and the set of increasing sequences with entries in :
Elements of can be identified with sequences , so can be considered as a subset of .
A preorder defined by the condition:
(*) if and only if there exists such that for all the inequalities
induces an equivalence relation in :
In particular, if and , then
and
for all and some . (Here, is the largest integer which does not exceed , .)
Definition 4.1. Elements of the quotient are called growth types. The growth type of (resp., of ) is denoted by (resp., by ). Also, we let . is the set of growth types of monotone functions (in the sense of [Hector&Hirsch1981]). The preorder induces a partial order (denoted again by ) in .
5 Geometric entropy
6 Invariant measures
7 Results on entropy
8 References
- [Ghys&Langevin&Walczak1988] É. Ghys, R. Langevin and P. Walczak, Entropie géométrique des feuilletages, Acta Math. 160 (1988), no.1-2, 105–142. MR926526 (89a:57034) Zbl 0666.57021
- [Haefliger1962a] A. Haefliger, Variétés feuilletées, Ann. Scuola Norm. Sup. Pisa (3) 16 (1962), 367–397. MR0189060 (32 #6487) Zbl 0196.25005
- [Hector&Hirsch1981] G. Hector and U. Hirsch, Introduction to the geometry of foliations. Part A, Friedr. Vieweg \& Sohn, Braunschweig, 1981. MR639738 (83d:57019) Zbl 0628.57001
- [Veblen&Whitehead1932] O. Veblen and J. Whitehead, The foundations of differential geometry, Cambridge Tracts in Math. a. Math. Phys. 29) London: Cambridge Univ. Press. IX, 97 S., 1932. Zbl 0005.21801
- [Walczak2004] P. Walczak, Dynamics of foliations, groups and pseudogroups, Birkhäuser Verlag, 2004. MR2056374 (2005d:57042) Zbl 1084.37022
To make the above precise, let us take a topological space and denote by Homeo the family of all homeomorphisms between open subsets of . If Homeo, then is its domain and .
Definition 2.1. A subfamily of Homeo is said to be a pseudogroup if it is closed under composition, inversion, restriction to open subdomains and unions. More precisely, should satisfy the following conditions:
(i) whenever and ,
(ii) whenever ,
(iii) whenever and is open,
(iv) if Homeo, is an open cover of and for any , then .
Moreover, we shall always assume that
(v] id (or, equivalently, ).
As examples, one may have (1) all the homeomorphisms between open sets of a topological space, (2) all the diffeomorhisms of a given class (say, , , between open sets of a manifold, (3) all the restrictions to open domains of elements of a given group of homeomorphisms of a given topological space. (In the last case, we say that the pseudogroup is generated by .) Any set of homeomorphisms bewteen open sets (with domains covering a space ) generates ma pseudogroup which is the smallest pseudogroup containing ; precisely a homeomorphism belongs to if and only if for any point there exist elements , exponents and a neighbourhood of such that on . If is finite, is said to be finitely generated.
3 Holonomy pesudogroups
Definition 3.1. A foliated atlas on a foliated manifold is said to be nice (also, nice is the covering of by the domains of the charts ) if
(i) the covering is locally finite,
(ii) for any , is an open cube,
(iii) if and , and , then there exists a foliated chart chart and such that is an open cube, contains the closure of and .
Since manifolds are supposed to be paracompact here, they are separable and hence nice coverings are denumerable. Nice coverings on compact manifolds are finite. On arbitrary foliated manfiolds, nice coverings do exist.
Given a nice covering of a foliated manifold . For any , let be the space of the plaques (i.e., connected components of intersections . being a leaf of ) of contained in . Equip with the quotient topology: two points of are equivalent iff they belong to the same plaque. is homeomorphic (-diffeomorphic when is -differentiable and ) to an open cube () via the map , where is a foliated chart on . The disjoint union
is called a complete transversal for . Transversality refers to the fact that, if is differentiable of class , , each of the spaces can be mapped homeomorphically onto a -submanifold transverse to : if and is the leaf of passing through , then
Completeness of means that every leaf of intersects at least one of the submanifolds .
Definition 3.2. Given a nice covering of a foliated manifold and two sets and such that the holonomy map , being the open subset of which consists of all the plaques of for which , is defined in the following way:
All the maps () generate a pseudogroup on . is called the holonomy pseudogroup of .
This means that any element of assigns to a plaque the end plaque of a chain (that is a sequence of plaques such that any two consequtive plaques intersect) which oroginates at .
Certainly, holonomy pseudogroups of arbitrary compact foliated manifolds are finitely generated. For example, gluing together two 2-dimensional Reeb foliations (see Foliations#Reeb Foliations) on one gets a foliation of the 3-dimensional sphere for which any arc intersecting the unique toral leaf is a complete transversal; can be identified with a segment (), the point of intersection with the number , while the holonomy group with the one on our segment generated by two maps such that , , snd contract their domains towards .
4 Growth
Let us begin with two non-decreasing sequences and of non-negative numbers. We shall say that "grows slower" that () whenever there exist positive constants and such that the inequalities
hold for all . We say that types of growth of our sequences and are the same whenever
Let now be the set of non-negative increasing functions defined on :
and the set of increasing sequences with entries in :
Elements of can be identified with sequences , so can be considered as a subset of .
A preorder defined by the condition:
(*) if and only if there exists such that for all the inequalities
induces an equivalence relation in :
In particular, if and , then
and
for all and some . (Here, is the largest integer which does not exceed , .)
Definition 4.1. Elements of the quotient are called growth types. The growth type of (resp., of ) is denoted by (resp., by ). Also, we let . is the set of growth types of monotone functions (in the sense of [Hector&Hirsch1981]). The preorder induces a partial order (denoted again by ) in .
5 Geometric entropy
6 Invariant measures
7 Results on entropy
8 References
- [Ghys&Langevin&Walczak1988] É. Ghys, R. Langevin and P. Walczak, Entropie géométrique des feuilletages, Acta Math. 160 (1988), no.1-2, 105–142. MR926526 (89a:57034) Zbl 0666.57021
- [Haefliger1962a] A. Haefliger, Variétés feuilletées, Ann. Scuola Norm. Sup. Pisa (3) 16 (1962), 367–397. MR0189060 (32 #6487) Zbl 0196.25005
- [Hector&Hirsch1981] G. Hector and U. Hirsch, Introduction to the geometry of foliations. Part A, Friedr. Vieweg \& Sohn, Braunschweig, 1981. MR639738 (83d:57019) Zbl 0628.57001
- [Veblen&Whitehead1932] O. Veblen and J. Whitehead, The foundations of differential geometry, Cambridge Tracts in Math. a. Math. Phys. 29) London: Cambridge Univ. Press. IX, 97 S., 1932. Zbl 0005.21801
- [Walczak2004] P. Walczak, Dynamics of foliations, groups and pseudogroups, Birkhäuser Verlag, 2004. MR2056374 (2005d:57042) Zbl 1084.37022
To make the above precise, let us take a topological space and denote by Homeo the family of all homeomorphisms between open subsets of . If Homeo, then is its domain and .
Definition 2.1. A subfamily of Homeo is said to be a pseudogroup if it is closed under composition, inversion, restriction to open subdomains and unions. More precisely, should satisfy the following conditions:
(i) whenever and ,
(ii) whenever ,
(iii) whenever and is open,
(iv) if Homeo, is an open cover of and for any , then .
Moreover, we shall always assume that
(v] id (or, equivalently, ).
As examples, one may have (1) all the homeomorphisms between open sets of a topological space, (2) all the diffeomorhisms of a given class (say, , , between open sets of a manifold, (3) all the restrictions to open domains of elements of a given group of homeomorphisms of a given topological space. (In the last case, we say that the pseudogroup is generated by .) Any set of homeomorphisms bewteen open sets (with domains covering a space ) generates ma pseudogroup which is the smallest pseudogroup containing ; precisely a homeomorphism belongs to if and only if for any point there exist elements , exponents and a neighbourhood of such that on . If is finite, is said to be finitely generated.
3 Holonomy pesudogroups
Definition 3.1. A foliated atlas on a foliated manifold is said to be nice (also, nice is the covering of by the domains of the charts ) if
(i) the covering is locally finite,
(ii) for any , is an open cube,
(iii) if and , and , then there exists a foliated chart chart and such that is an open cube, contains the closure of and .
Since manifolds are supposed to be paracompact here, they are separable and hence nice coverings are denumerable. Nice coverings on compact manifolds are finite. On arbitrary foliated manfiolds, nice coverings do exist.
Given a nice covering of a foliated manifold . For any , let be the space of the plaques (i.e., connected components of intersections . being a leaf of ) of contained in . Equip with the quotient topology: two points of are equivalent iff they belong to the same plaque. is homeomorphic (-diffeomorphic when is -differentiable and ) to an open cube () via the map , where is a foliated chart on . The disjoint union
is called a complete transversal for . Transversality refers to the fact that, if is differentiable of class , , each of the spaces can be mapped homeomorphically onto a -submanifold transverse to : if and is the leaf of passing through , then
Completeness of means that every leaf of intersects at least one of the submanifolds .
Definition 3.2. Given a nice covering of a foliated manifold and two sets and such that the holonomy map , being the open subset of which consists of all the plaques of for which , is defined in the following way:
All the maps () generate a pseudogroup on . is called the holonomy pseudogroup of .
This means that any element of assigns to a plaque the end plaque of a chain (that is a sequence of plaques such that any two consequtive plaques intersect) which oroginates at .
Certainly, holonomy pseudogroups of arbitrary compact foliated manifolds are finitely generated. For example, gluing together two 2-dimensional Reeb foliations (see Foliations#Reeb Foliations) on one gets a foliation of the 3-dimensional sphere for which any arc intersecting the unique toral leaf is a complete transversal; can be identified with a segment (), the point of intersection with the number , while the holonomy group with the one on our segment generated by two maps such that , , snd contract their domains towards .
4 Growth
Let us begin with two non-decreasing sequences and of non-negative numbers. We shall say that "grows slower" that () whenever there exist positive constants and such that the inequalities
hold for all . We say that types of growth of our sequences and are the same whenever
Let now be the set of non-negative increasing functions defined on :
and the set of increasing sequences with entries in :
Elements of can be identified with sequences , so can be considered as a subset of .
A preorder defined by the condition:
(*) if and only if there exists such that for all the inequalities
induces an equivalence relation in :
In particular, if and , then
and
for all and some . (Here, is the largest integer which does not exceed , .)
Definition 4.1. Elements of the quotient are called growth types. The growth type of (resp., of ) is denoted by (resp., by ). Also, we let . is the set of growth types of monotone functions (in the sense of [Hector&Hirsch1981]). The preorder induces a partial order (denoted again by ) in .
5 Geometric entropy
6 Invariant measures
7 Results on entropy
8 References
- [Ghys&Langevin&Walczak1988] É. Ghys, R. Langevin and P. Walczak, Entropie géométrique des feuilletages, Acta Math. 160 (1988), no.1-2, 105–142. MR926526 (89a:57034) Zbl 0666.57021
- [Haefliger1962a] A. Haefliger, Variétés feuilletées, Ann. Scuola Norm. Sup. Pisa (3) 16 (1962), 367–397. MR0189060 (32 #6487) Zbl 0196.25005
- [Hector&Hirsch1981] G. Hector and U. Hirsch, Introduction to the geometry of foliations. Part A, Friedr. Vieweg \& Sohn, Braunschweig, 1981. MR639738 (83d:57019) Zbl 0628.57001
- [Veblen&Whitehead1932] O. Veblen and J. Whitehead, The foundations of differential geometry, Cambridge Tracts in Math. a. Math. Phys. 29) London: Cambridge Univ. Press. IX, 97 S., 1932. Zbl 0005.21801
- [Walczak2004] P. Walczak, Dynamics of foliations, groups and pseudogroups, Birkhäuser Verlag, 2004. MR2056374 (2005d:57042) Zbl 1084.37022