0708-1300/Class notes for Tuesday, September 25: Difference between revisions

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Dror's Notes

• Class photo is on Thursday, show up and be at your best! More seriously -
  • The class photo is of course not mandatory, and if you are afraid of google learning about you, you should not be in it.
  • If you want to be in the photo but can't make it on Thursday, I'll take a picture of you some other time and add it as an inset to the main picture.

• I just got the following email message, which some of you may find interesting:

NSERC - CMS Math in Moscow Scholarships

The Natural Sciences and Engineering Research Council (NSERC) and the
Canadian Mathematical Society (CMS) support scholarships at $9,000
each. Canadian students registered in a mathematics or computer
science program are eligible.

The scholarships are to attend a semester at the small elite Moscow
Independent University.

Math in Moscow program
www.mccme.ru/mathinmoscow/
Application details
www.cms.math.ca/bulletins/Moscow_web/

For additional information please see your department or call the CMS
at 613-562-5702.

Deadline September 30, 2007 to attend the Winter 2008 semester.

Class Notes - First hour

Recall from last class we were proving the equivalence of the two definitions for a smooth manifold. The only nontrivial point that remained to be proved was that if we started with the definition of a manifold in the sense of functional structures and produced charts ${\displaystyle \varphi ,\psi }$ that these charts would satisfy the property of a manifold, defined in the atlas sense, that ${\displaystyle \psi \circ \varphi ^{-1}}$ is smooth where defined.

Proof

${\displaystyle \psi \circ \varphi ^{-1}}$:Rⁿ${\displaystyle \rightarrow }$Rⁿ is smooth ${\displaystyle \leftrightarrow }$ ${\displaystyle (\psi \circ \varphi ^{-1})_{i}}$:Rⁿ${\displaystyle \rightarrow }$R is smooth ${\displaystyle \forall }$ i ${\displaystyle \leftrightarrow }$ ${\displaystyle \pi _{i}\circ \psi \circ \varphi ^{-1}}$ is smooth where ${\displaystyle \pi _{i}}$ is the ${\displaystyle i^{th}}$ coordinate projection map.

Now, since ${\displaystyle \pi _{i}}$ is always smooth, ${\displaystyle \pi _{i}\in F_{R^{n}}(U_{\psi }^{'})}$

But then we have ${\displaystyle \pi _{i}\circ \psi \in F_{M}(U_{\psi })}$ and so, by a property of functional structures, ${\displaystyle \pi _{i}\circ \psi |_{U_{\varphi }\bigcap U_{\psi }}\in F_{M}(U_{\varphi }\bigcap U_{\psi })}$ and hence ${\displaystyle \pi _{i}\circ \psi \circ \varphi ^{-1}\in F_{R^{n}}}$ where it is defined and thus is smooth. QED

Definition 1 (induced structure) Suppose ${\displaystyle \pi :X\rightarrow Y}$ and suppose Y is equipped with a functional structure ${\displaystyle F_{Y}}$ then the "induced functional structure" on X is

${\displaystyle F_{X}(U)=\{f:U\rightarrow R\ |\ \exists g\in F_{Y}(V)\ such\ that\ V\supset \pi (U)\ and\ f=g\circ \pi \}}$

Claim: this does in fact define a functional structure on X

Definition 2 This is the reverse definition of that given directly above. Let ${\displaystyle \pi :X\rightarrow Y}$ and let X be equipped with a functional structure ${\displaystyle F_{X}}$. Then we get a functional structure on Y by ${\displaystyle F_{Y}(V)=\{g:V\rightarrow R\ |\ g\circ \pi \in F_{X}(\pi ^{-1}(V)\}}$ Claim: this does in fact define a functional structure on X

Example 1 Let ${\displaystyle S^{2}=R^{3}-\{0\}/}$~ where the equivalence relation ~ is given by x~${\displaystyle \alpha }$x for ${\displaystyle \alpha }$>0 We thus get a canonical projection map ${\displaystyle \pi :R^{3}-\{0\}\rightarrow S^{2}}$ and hence, there is an induced functional structure on ${\displaystyle S^{2}}$. Claim: 1) This induced functional structure makes ${\displaystyle S^{2}}$ into a manifold 2) This resulting manifold is the same manifold as from the atlas definition given previously

Example 2 Consider the torus thought of as ${\displaystyle T^{2}=R^{2}/Z^{2}}$, i.e., the real plane with the equivalence relation that (x,y)~(x+n,y+m) for (x,y) in ${\displaystyle R^{2}}$and (n,m) in ${\displaystyle Z^{2}}$

As in the previous example, the torus inherits a functional structure from the real plane we must again check that 1) We get a manifold 2) This is the same manifold as we had previously with the atlas definition

Example 3 Let ${\displaystyle CP^{n}}$ denote the n dimensional complex projective space, that is, ${\displaystyle CP^{n}=C^{n+1}-\{0\}/}$~ where ${\displaystyle [z_{0},...,z_{n}]}$ ~ ${\displaystyle [\alpha z_{0},...,\alpha z_{n}]}$ where ${\displaystyle \alpha \in C}$

Again, this space inherits a functional structure from ${\displaystyle C^{n+1}}$ and we again need to claim that this yields a manifold.

Proof of Claim

We consider the subsets ${\displaystyle CP^{n}\supset U_{i}=\{[z_{0},...,z_{n}]\ |\ z_{i}\neq 0\}}$ for ${\displaystyle 0\leq i\leq n}$

Clearly ${\displaystyle \bigcup U_{i}=CP^{n}}$

Now, for each ${\displaystyle p\in U_{i}}$ there is a unique representative for its equivalence class of the form ${\displaystyle [z_{0},...,1,...,z_{n}]}$ where the 1 is at the ith location.

We thus can get a map from ${\displaystyle \varphi _{i}:U_{i}\rightarrow C^{n}=R^{2n}}$ by ${\displaystyle p\mapsto [z_{0}/z_{i},...,z_{i-1}/z_{i},z_{i+1}/z_{i},...,z_{n}/z_{i}]}$ Hence we have shown (loosely) that our functional structure is locally isormophic to ${\displaystyle (R,C^{\infty })}$

Definition 3 Product Manifolds

Suppose ${\displaystyle M^{m}}$ and ${\displaystyle N^{n}}$ are manifolds. Then the product manifold, on the set MxN has an atlas given by ${\displaystyle \{\varphi \times \psi :U\times V\rightarrow U'\times V'\in R^{m}\times R^{n}\ |\varphi :U\rightarrow U'\subset R^{m}\ and\ \psi :V\rightarrow V'\subset R^{n}}$ are charts in resp. manifolds}

Claim: This does in fact yield a manifold

Example 4 It can be checked that ${\displaystyle T^{2}=S^{1}\times S^{1}}$ gives the torus a manifold structure, by the product manifold, that is indeed the same as the normal structure given previously.