Survey
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Download 3 Topology of a manifold
Document related concepts
Sheaf (mathematics) wikipedia , lookup
Surface (topology) wikipedia , lookup
Covering space wikipedia , lookup
Differential form wikipedia , lookup
Brouwer fixed-point theorem wikipedia , lookup
Continuous function wikipedia , lookup
PoincarΓ© conjecture wikipedia , lookup
Geometrization conjecture wikipedia , lookup
General topology wikipedia , lookup
Grothendieck topology wikipedia , lookup
Orientability wikipedia , lookup
Transcript
THEODORE VORONOV
§3
DIFFERENTIABLE MANIFOLDS. Fall 2009
Topology of a manifold
Last updated: November 17, 2009.
3.1
Basic topological properties of manifolds
Consider a manifold π = (π, π), where π = (π : π β π ) is a smooth atlas
deο¬ning the manifold structure on the set π . Here π β βπ and π β π .
Let us assume that this atlas is maximal, i.e., it is the union of all equivalent
atlases.
Deο¬nition 3.1. A subset π΄ β π is open if and only if for each chart in the
maximal atlas π, the set πβ1 (π΄ β© π ) β βπ is open.
Example 3.1. The codomain π of each chart is an open set.
Consider unions and intersections of open subsets of a manifold. Let
π : π β π be a particular chart. (For the simplicity of notation we have
dropped an index πΌ.) For an arbitrary family of sets π΄π β π we have
βͺ
βͺ
βͺ
πβ1 (( π΄π ) β© π ) = πβ1 ( (π΄π β© π )) =
πβ1 (π΄π β© π )),
β©
β©
β©
πβ1 (( π΄π ) β© π ) = πβ1 ( (π΄π β© π )) =
πβ1 (π΄π β© π )).
because π is a bijection.
From here follows a theorem:
Theorem 3.1. Open subsets of a manifold π (deο¬ned as above) satisfy the
axioms of a topology.
Therefore each manifold can be considered as a topological space. We
shall refer to the topology deο¬ned above as to the manifold topology or the
topology given by a manifold structure.
Recall the notion of an open cover of a topological space π. It is a
collection of open sets π = (ππΌ ) such that βͺππΌ = π.
Example 3.2. If π = (ππΌ : ππΌ β ππΌ ) is an atlas for a manifold π , then
(ππΌ ) is an open cover of π , which is often referred to as a βcoordinate coverβ.
There is a useful lemma:
1
THEODORE VORONOV
DIFFERENTIABLE MANIFOLDS. Fall 2009
Lemma 3.1. Suppose (ππΌ ) is an open cover of π. A subset π΄ β π is open
if and only if π΄ β© ππΌ is open for all πΌ.
Proof.
βͺ If π΄ is open, then all intersections with ππΌ are open. Conversely,
π΄ = πΌ (π΄ β© ππΌ ), which is a union of open sets and thus open.
For manifolds we can say more. Suppose πβ² = (ππΌ : ππΌ ) β ππΌ is a
particular atlas for π , not necessarily maximal.
Lemma 3.2. A set π β π is open if πβ1
πΌ (π β© ππΌ ) are open, for all charts
in πβ² .
Therefore it is suο¬cient to check the intersections with the codomains for
a particular atlas!
Suppose there is already some topology on the set π . Under which
condition will it coincide with the topology induced by a manifold structure
(the βmanifold topologyβ)?
Theorem 3.2. A topology π on π coincides with the manifold topology if
and only if for some atlas all sets ππΌ are open in π and all maps ππΌ are
homeomorphisms w.r.t. π .
Proof. Consider the manifold topology. The sets ππΌ are open by deο¬nition
of this topology. Why ππΌ is continuous ? Take any π β ππΌ . πβ1
πΌ (π ) β ππΌ .
β1
β1
If π = ππΌ (ππΌ (π )) is open, then by deο¬nition ππΌ (π ) is open.
Conversely, let ππΌ be open in some π and ππΌ be homeomorphisms w.r.t.
π . Let π be an open set in π . Then π β© ππΌ is open, and since ππΌ is a
homeomorphism, then ππΌ (π β© ππΌ ) is also open. That means, π is open in
the manifold topology. Now let π be open in the manifold topology. Thus
ππΌ (π) is open in βπ . Since ππ are homeomorphisms with respect to π , it
follows that all intersections π β© ππΌ are open in π . Applying Lemma 3.1, we
obtain that π is open in π .
Example 3.3. The manifold topology of π π coincides with the usual (subspace) topology.
Consider π π β βπ+1 with the induced topology. Since subsets π π β π
and π π β π are open in this topology, and the formulas for stereographic
projection are given by rational functions (both direct and inverse maps),
then by Theorem 3.2 the subspace topology and the topology induced by
manifold structure coincide.
2
THEODORE VORONOV
DIFFERENTIABLE MANIFOLDS. Fall 2009
Continuity: in terms of neighborhoods, hence in coordinates.
What is the relation between smoothness and continuity?
Theorem 3.3. A smooth map is continuous.
Proof proves follows from the deο¬nition of continuity in terms of neighborhoods.
Recall such fundamental notions as compactness and connectedness.
Recall that a topological space is called compact, if one can extract a ο¬nite
subcover from its any open cover. Note that a subspace π of a topological
space π is compact (in induced topology), iο¬ one can extract ο¬nite βͺ
subcover
of any open cover of π in π, i.e., a collection (ππΌ ) such that π β (ππΌ ).
We shall use the following properties of compactness.
Theorem 3.4. Any closed subspace of a compact space is compact.
Proof. Consider an open cover of π in π. Add π β π to this collection. Then
we have an open cover of π. Extract a ο¬nite subcover and for aesthetical
purposes throw away π β π, if it is still present. This is a ο¬nite subcover of
π.
Theorem 3.5. Let π : π β π be continuous, π compact. Then π (π) is
compact.
Proof. Let (ππΌ ) be an open cover of π (π). Then π β1 (ππΌ ) is an open cover
β1
of βͺ
π. Extract a βͺο¬nite subcover πβͺ
(ππΌπ ), π = 1, . . . , π . Then π (π) =
π ( π β1 (ππΌπ )) = π (π β1 (ππΌπ )) = ππΌπ .
Theorem 3.6 (HeineβBorel). A subspace of βπ is compact, iο¬ it is closed
and bounded (i.e. is contained in some ball of radius π
< β).
Examples.
π π is compact.
Now we shall discuss properties of manifolds related to connectedness.
...............................
Example 3.4. π π is connected.
3
THEODORE VORONOV
3.2
DIFFERENTIABLE MANIFOLDS. Fall 2009
Partitions of unity and embedding into βπ
We have to admit an embarrassing fact: for a general manifold π we do not
have tools allowing to show the existence of smooth functions deο¬ned everywhere on π (besides constants). On βπ we have plenty of functions: ο¬rst of
all, the coordinate functions π₯π , then polynomials and various other smooth
functions of π₯1 , . . . , π₯π . By contrast, in the absence of global coordinates,
how one can ο¬nd a non-trivial smooth functions on a manifold?
If, however, a manifold π π is βembeddedβ into some βπ as some kind of
multidimensional surface (later we shall explain it precisely), then there will
be plenty of smooth functions: all restrictions of the standard coordinates
π¦ 1 , . . . , π¦ π on π π . So the questions about having βenough smooth functionsβ
and about the possibility to embed a manifold into a Euclidean space are
closely related.
Let us make the following observation. For a manifold (or any topological
space) to be realized as a subspace of βπ , it must satisfy some a priori
topological conditions.
Recall that a topological space is Hausdorο¬ if for any two points π₯ β= π¦
it is possible to ο¬nd open sets ππ₯ β π₯ and ππ¦ β π¦ s.t. ππ₯ β© ππ¦ = β
.
Example 3.5. All metric spaces are Hausdorο¬, in particular βπ , and any
subspace of a Hausdorο¬ space is Hausdorο¬. Hence all examples of manifolds
embedded in βπ (βmultidimensional surfacesβ) are Hausdorο¬.
Recall that a base of a topological space is a family of open sets such that
an arbitrary open set is the union of sets from that family.
Example 3.6. Suppose π is a metric space (e.g. βπ ). The collection of all
open balls is a base.
Example 3.7. For βπ it is possible to show that it is suο¬cient to take
all open balls with rational centers (the coordinates of the centers must be
rational numbers) and rational radii.
A topological space is called second-countable if it has a countable base 1 .
As we have seen, βπ is second-countable. Clearly, any subspace of a secondcountable space is second-countable too.
1
This traditional terminology comes from certain βο¬rstβ and βsecondβ βcountability
conditionsβ considered in set-theoretic topology.
4
THEODORE VORONOV
DIFFERENTIABLE MANIFOLDS. Fall 2009
Deο¬nition 3.2 (Amended). A manifold from now on is what we have previously called a manifold satisfying, in addition, the requirements that as a
topological space it is Hausdorο¬ and second-countable.
Remark 3.1. A manifold is second-countable if and only if it has a countable atlas. Indeed, suppose it is second-countable. That means there is a
countable base β¬ = (π΅π ). Consider an arbitrary atlas (ππΌ : ππΌ β ππΌ ). Then
every open set ππΌ is the union of some sets π΅π ; hence these particular π΅π βs
admit local coordinate systems as the restrictions of the coordinate system
on ππΌ . Thus we arrive at a new atlas the codomains of which are certain
elements of the family β¬ = (π΅π ). In particular, it is countable. Conversely,
suppose there is a countable atlas on a manifold π π . To construct a countable base for π π , take countable bases for the domains of each chart (as an
open subset of βπ ), consider their images in π π and take their union. It is
a countable family of open sets in π π and every open set in π is the union
of some elements of this family (since it is the union of its intersections with
the chart codomains).
With these conditions imposed it is possible to show that there is enough
smooth functions. It turns out that it is necessary and suο¬cient to impose
these topological restrictions on a manifold π to guarantee a good supply of
C β functions. It is done below. (Without them, one can construct βpathologicalβ examples where the only smooth functions are constants. On the
other hand, with the restrictions described below, we shall be able to show
that a manifold can be embedded into a Euclidean space of suο¬ciently large
dimension, which guarantees an abundance of smooth functions.)
Recall that the support of a function (notation: Supp π ) is the closure of
the subset where the function does not vanish.
Lemma 3.3 (Bump functions). For any point π β π of a smooth manifold
π there is a nonnegative smooth function ππ β πΆ β (π ) (a βbump functionβ)
compactly supported in a neighborhood of π and which is identically 1 on a
smaller neighborhood.
Proof. First let us prove the following. Let πΆπ be a cube {β£π₯π β£ β€ π, βπ} in
βπ . There is a πΆ β -function which equals zero outside πΆ2 and equals one on
πΆ1 (this will be the βlocalβ part of the lemma).
Let π₯ β β. Consider the function π (π₯) deο¬ned as πβ1/π₯ for π₯ > 0 and zero
for π₯ β€ 0. It is πΆ β . Deο¬ne β(π₯) := π (π₯)/(π (π₯)+π (1βπ₯)). Since π (1βπ₯) = 0
5
THEODORE VORONOV
DIFFERENTIABLE MANIFOLDS. Fall 2009
for π₯ > 1, the function β is identically 0 for π₯ β€ 0 and identically 1 for π₯ β₯ 1.
Then the function π(π₯) := β(π₯ + 2)β(2 β π₯) is zero for π₯ β₯ 2 or π₯ β€ β2
and equals 1 for β£π₯β£ β€ 1. Taking the product of such functions for each
coordinate, we obtain the required function on βπ .
Transferring this to a manifold relies on the Hausdorο¬ condition.
The details are as follows. Consider a manifold π and a point π β π . Consider
a coordinate neighborhood π around π. From the local construction we have a smooth
function ππ deο¬ned on π such that it is 1 near π and its support is contained in some
open π β π homeomorphic to an open ball or a cube. In particular, the closure of π
is homeomorphic to a closed ball, hence is compact. Extend ππ from π to π β π by
zero. It is necessary to prove that the result is smooth. It is suο¬cient to prove that for
any π β π β π there is a whole neighborhood π on which ππ is identically zero. Fix π.
¯ Since π is Hausdorο¬, there are disjoint open neighborhoods
Consider all points π β π.
¯ is compact, we can extract a ο¬nite number
ππ¦π§ and ππ¦π§ of π and π respectively. Since π
¯ Then the intersection β© ππ¦π§ is an open
of neighborhoods ππ¦π§π , π = 1, . . . , π covering π.
π
¯ So we can take it as π β π¦, and the
neighborhood of π and does not intersect with π.
function ππ is identically zero on π , hence smooth at π.
From the proof it follows that it is possible to construct a bump function
such that it is compactly supported in a given neighborhood of π.
Having bump functions on a manifold is already suο¬cient for showing that
there are many global smooth functions. Indeed, take an arbitrary smooth
function deο¬ned in a neighborhood of π β π . Then, by multiplying it by
a suitable bump function (compactly supported inside a smaller neighborhood), it is possible to extend it by zero to the whole manifold π . We shall
use this many times in the future.
A collection of subsets π΄π β π is said to be locally ο¬nite if each point
π₯ β π has a neighborhood with the empty intersection with all π΄π except
for a ο¬nite number of indices π.
Deο¬nition 3.3. A partition of unity on a topological space π is a collection
of nonnegative continuous functions (ππ ) such that the collection of their
supports (Supp ππ ) is locally ο¬nite, and for any π₯ β π
β
ππ (π₯) = 1.
(1)
π
(For each point the sum is actually ο¬nite.)
A partition of unity (ππ ) is called subordinate to a cover (ππΌ ) if for each
π there is an open set ππΌ , where πΌ = πΌ(π), such that Supp ππ β ππΌ . We say
6
THEODORE VORONOV
DIFFERENTIABLE MANIFOLDS. Fall 2009
that a partition of unity (ππΌ ) is subordinate to an open cover (ππΌ ) with the
same set of indices if Supp ππΌ β ππΌ for each πΌ.
Obviously, everything simplify greatly for ο¬nite covers and ο¬nite partitions of unity.
For manifolds, we shall look for smooth partitions of unity.
Theorem 3.7. For any open cover (ππΌ ) of a smooth manifold π there exists
a smooth partition of unity subordinate to this cover. It can be chosen with
one of the two additional properties: either
(1) the partition of unity (ππ ) is countable and all functions ππ belonging
to it are compactly supported;
or
(2) the partition of unity is with the same set of indices, (ππΌ ) so that
Supp ππΌ β ππΌ , for all πΌ.
In the latter case only a countable number of functions are not identically
zero.
Proof. A proof is based on the existence of bump functions and uses, in
addition, the condition of second-countability. We shall give a proof only for
case when the manifold π is compact. It is not necessary for the statement,
but the proof simpliο¬es greatly.
Take an open over of π , (ππΌ ). For each point ππΌ β ππΌ consider a bump
function πππΌ chosen in such a way that Supp πππΌ β ππΌ . There are open
neighborhoods πππΌ β ππΌ in ππΌ such that πππΌ = 1 on πππΌ . Consider the
collection (πππΌ ) for all πΌ and all ππΌ β ππΌ as an open cover of π (it is a
βreο¬nementβ of the cover (ππΌ )). We can extract a ο¬nite subcover. Denote
its elements as ππ , where π = 1, . . . , π , so that ππ = π(ππΌ )π ; we have
ππ β ππΌπ . Note that ππ := π(ππΌ )π is > 0 on ππ . We deο¬ne
ππ :=
ππ
.
π1 + . . . + ππ
It is well-deο¬ned because all ππ are non-negative
and at each point at least
β
one ππ is positive. Clearly, ππ β₯ 0 and
ππ = 1. Hence we have obtained
a ο¬nite partition of unity. Also, Supp ππ = Supp ππ β ππΌπ . To obtain a
partition of unity with the same set of indices, consider functions βπΌ deο¬ned
as ππ for πΌ = πΌπ and as 0 otherwise. Note that in both versions the functions
in the partition of zero have compact support (which would not be the case
for a non-compact manifold).
7
THEODORE VORONOV
DIFFERENTIABLE MANIFOLDS. Fall 2009
Example 3.8. A partition of unity for the sphere π 2 . Use spherical coordinates. One can deο¬ne non-negative functions π1 (π) and π2 (π) such that
π1 (π) = 1 for 0 β€ π β€ π/3 and π1 (π) = 0 for 2π/3 β€ π β€ π and, similarly,
π2 (π) such that π2 (π) = 1 for 2π/3 β€ π β€ π and π2 (π) = 0 for 0 β€ π β€ π/3.
They are bump functions for the points π and π respectively. We set
π1 :=
π1
π1 + π2
and π2 :=
π2
.
π1 + π2
Hence (π1 , π2 ) is a partition of unity subordinate to the open cover (π1 , π2 )
where π1 = π 2 β {π} and π2 = π 2 β {π }.
Corollary 3.1. Let πΆ0 , πΆ1 β π be closed subsets such that πΆ0 β© πΆ1 = β
.
There is a function π β πΆ β (π ) such that π β‘ 1 on πΆ1 and π β‘ 0 on πΆ0 .
Proof. Consider the open cover π = π0 βͺ π1 , where ππΌ := π β πΆπΌ and a
subordinate partition of unity π0 + π1 = 1. Take π := π0 . By deο¬nition,
Supp π0 β π0 = π β πΆ0 . Thus π = 0 on πΆ0 . Similarly, π1 = 0 on πΆ1 . Thus
π = π0 = 1 β π1 = 1 on πΆ1 .
Functions constructed in Corollary 3.1 are called Urysohn functions for
the pair πΆ0 , πΆ1 . On a topological space the existence of (continuous) Urysohn
functions is a separation property which is stronger than being Hausdorο¬.
We are now ready to obtain ο¬rst applications of the existence of partitions
of unity.
Deο¬nition 3.4. A (smooth) map of manifolds π : π π β π π is an embedding
if it is injective and all the tangent maps ππ (π) : ππ π β ππ (π) π are also
injective (that is, are monomorphisms of vector spaces).
Theorem 3.8. For any compact manifold π π there is an embedding
π : π β βπ ,
for a suο¬ciently large π .
Proof. Recall the construction of bump functions above. Starting from an
arbitrary atlas for π , we can always construct a ο¬nite atlas with coordinate
domains ππ , π = 1, . . . , π, having the following property: there are smaller
open sets ππ β ππ and non-negative functions ππ such that each ππ = 1
identically on ππ and ππ vanish on π β ππ and the sets ππ still give a cover
8
THEODORE VORONOV
DIFFERENTIABLE MANIFOLDS. Fall 2009
of π . Let π₯ππ β πΆ β (ππ ) be the coordinate functions on ππ . Deο¬ne the
functions π¦ππ β πΆ β (π ) as ππ β
π₯ππ on ππ and as zero on π β ππ . (This is welldeο¬ned, compare the construction of bump functions). Deο¬ne the following
smooth map: π : π β βπ(π+1) , by the formula
π : π₯ 7β (π¦ππ (π₯), ππ (π₯)).
(2)
This map is injective. Indeed, suppose π (π₯) = π (π¦) for some π₯, π¦ β π . Since
the sets (ππ ) cover π , there is some π such that ππ (π₯) = 1. Hence ππ (π¦) = 1.
In particular, it follows that π₯ and π¦ are in the same coordinate domain ππ
(because ππ = 0 on π β ππ ). By deο¬nition of π¦ππ , then all their coordinates
there coincide, and hence π₯ = π¦. Consider now the Jacobi matrix
( π
)
βπ¦π βππ
,
,
βπ₯ππ βπ₯ππ
which has π rows and (π + 1)π columns. For each π₯ β π , there is an open
βπ¦ π
βπ₯π
set ππ containing π₯ where ππ = 1 identically. Thus βπ₯ππ = βπ₯ππ = πΏππ (no
π
π
summation over π!). Hence the rank of the Jacobi matrix is π.
Thus any compact manifold can be considered as a subspace of a Euclidean space. This is true for non-compact manifolds, too, but the proof for
them is more sophisticated.
3.3
Whitney Theorem
What is the dimension π ? Is it possible to minimize it?
We use the following statement (basically, from analysis) without proof:
Lemma 3.4 (Corollary of Sardβs Lemma). A smooth map πΉ : π π β π π
cannot be surjective if π < π.
Theorem 3.9 (Whitney). A manifold π π of dimension π can be embedded
into βπ with π = 2π + 1.
Proof. Suppose that an embedding π β βπ is given. Is it possible to
decrease the number π ? We can identify π with its image in βπ . Consider
the orthogonal projection on the hyperplane πβ₯ β βπ for some direction
π β βπ π β1 . The projection is injective on π β βπ if for any two distinct
9
THEODORE VORONOV
DIFFERENTIABLE MANIFOLDS. Fall 2009
points π and π in π , the vector π β π β βπ is not parallel to π. (That
is, it does not belong to π.) In the same way, the projection is injective on
tangent vectors if no non-zero vector tangent to π is parallel to π. Denote
Λ := π × π β Ξ where Ξ = {(π, π)} is the βdiagonalβ. Denote π β² π :=
π
π π β π , i.e., the manifold of all non-zero tangent vectors. Consider the
Λ βͺ π β² π . We have a map π
Λ βͺ π β² π β βπ π β1 sending a pair
disjoint union π
(π, π) to the line spanned by π β π β βπ and a tangent vector π β= 0 to the
line [π]. It is smooth and we can apply the corollary of Sardβs lemma. This
Λ βͺ π β² π ) < dim βπ π β1 = π β 1, i.e.,
map is not onto as long as 2π = dim(π
π > 2π + 1. That means that by applying projections, the dimension of the
ambient space can be reduced to 2π + 1.
10
