0708-1300/Homework Assignment 5: Difference between revisions

0708-1300/Navigation Panel   Add your name / see who's in! # Week of... Links Fall Semester 1 Sep 10 About, Tue, Thu 2 Sep 17 Tue, HW1, Thu 3 Sep 24 Tue, Photo, Thu 4 Oct 1 Questionnaire, Tue, HW2, Thu 5 Oct 8 Thanksgiving, Tue, Thu 6 Oct 15 Tue, HW3, Thu 7 Oct 22 Tue, Thu 8 Oct 29 Tue, HW4, Thu, Hilbert sphere 9 Nov 5 Tue,Thu, TE1 10 Nov 12 Tue, Thu 11 Nov 19 Tue, Thu, HW5 12 Nov 26 Tue, Thu 13 Dec 3 Tue, Thu, HW6 Spring Semester 14 Jan 7 Tue, Thu, HW7 15 Jan 14 Tue, Thu 16 Jan 21 Tue, Thu, HW8 17 Jan 28 Tue, Thu 18 Feb 4 Tue 19 Feb 11 TE2, Tue, HW9, Thu, Feb 17: last chance to drop class R Feb 18 Reading week 20 Feb 25 Tue, Thu, HW10 21 Mar 3 Tue, Thu 22 Mar 10 Tue, Thu, HW11 23 Mar 17 Tue, Thu 24 Mar 24 Tue, HW12, Thu 25 Mar 31 Referendum,Tue, Thu 26 Apr 7 Tue, Thu R Apr 14 Office hours R Apr 21 Office hours F Apr 28 Office hours, Final (Fri, May 2) Register of Good Deeds Errata to Bredon's Book

Reading

Read sections 1-3 of chapter V of Bredon's book three times:

• First time as if you were reading a novel - quickly and without too much attention to detail, just to learn what the main keywords and concepts and goals are.
• Second time like you were studying for an exam on the subject - slowly and not skipping anything, verifying every little detail.
• And then a third time, again at a quicker pace, to remind yourself of the bigger picture all those little details are there to paint.

Also, do the same with your own class notes - much of what we do for this part of the class is not in the textbook!

Doing

Solve all of the following problems, but submit only your solutions of problems *,* and *:

Problem 1. Let ${\displaystyle M^{n}}$ be a manifold. Show that the following definitions for the orientability of ${\displaystyle M}$ are equivalent:

1. There exists a nowhere vanishing ${\displaystyle n}$-form on ${\displaystyle M}$.
2. There exists an atlas ${\displaystyle \{(U_{\alpha },\phi _{\alpha }:U_{\alpha }\to {\mathbb {R} }^{n})\}}$ for ${\displaystyle M}$, so that ${\displaystyle \det(\phi _{\alpha }\phi _{\beta }^{-1})>0}$ wherever that makes sense.

Problem 2. Show that the tangent space ${\displaystyle TM}$ of any manifold ${\displaystyle M}$ is orientable.

Problem 3.

1. Show that if ${\displaystyle M}$ and ${\displaystyle N}$ are orientable then so is ${\displaystyle M\times N}$.
2. Show that if ${\displaystyle M}$ and ${\displaystyle M\times N}$ are orientable then so is ${\displaystyle N}$.

Problem 4. Show that ${\displaystyle S^{n}}$ is always orientable.

Problem 5. Recall that a form is called closed if it is in the kernel of ${\displaystyle d}$ and exact if it is in the image of ${\displaystyle d}$. Show that every exact form is closed.

Problem 6. Let ${\displaystyle f:{\mathbb {R} }_{t}\to S^{1}\subset {\mathbb {C} }}$ be given by ${\displaystyle f(t)=e^{it}}$.

1. Show that there exists a unique ${\displaystyle \omega \in \Omega ^{1}(S^{1})}$ such that ${\displaystyle f^{\star }\omega =dt}$.
2. Show that ${\displaystyle \omega }$ is closed but not exact.

Problem 7. Show, directly from the definitions, that every closed 1-form on ${\displaystyle {\mathbb {R} }^{2}}$ is exact.

Problem 8. Compute the integral ${\displaystyle \int _{S^{2}}zdx\wedge dy}$ twice:

1. Using Stokes' theorem.
2. Directly from the definition, by using a one- or two-chart atlas for ${\displaystyle S^{2}}$.

(Repeat 1 and 2 until they stop giving different answers).

Problem 9. Show that the form ${\displaystyle \omega =xdy\wedge dz+ydz\wedge dx+zdx\wedge dy\in \Omega ^{2}({\mathbb {R} }_{x,y,z}^{3})}$ is invariant under rigid orientation-preserving rotations of ${\displaystyle {\mathbb {R} }^{3}}$. That is, if ${\displaystyle A}$ is such a rotation matrix (${\displaystyle AA^{T}=I}$ and ${\displaystyle \det A=1}$) considered also as a linear transformation ${\displaystyle A:{\mathbb {R} }^{3}\to {\mathbb {R} }^{3}}$, then ${\displaystyle A^{\star }\omega =\omega }$.

Due Date

This assignment is due in class on Thursday December 6, 2007.

Just for Fun