0708-1300/Homework Assignment 9: 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, reread and rereread your notes to this point, and make sure that you really, really really, really really really understand everything in them. Do the same every week!

Doing

(Problems 1,2,4,5 below are taken with slight modifications from Hatcher's book, pages 79-80).

1. Show that if ${\displaystyle p_{1}\colon X_{1}\to B_{1}}$ and ${\displaystyle p_{2}\colon X_{2}\to B_{2}}$ are covering spaces, then so is their product ${\displaystyle p_{1}\times p_{2}\colon X_{1}\times X_{2}\to B_{1}\times B_{2}}$.
2. Construct (i.e., describe in explicit terms) a simply-connected covering space of the space ${\displaystyle X\subset \mathbb {R} ^{3}}$ that is the union of a sphere and a diameter. Do the same when ${\displaystyle X}$ is the union of a sphere and a circle intersecting it in two points.
3. Do the same to the space ${\displaystyle Y}$ of the term test: ${\displaystyle Y=\{z\in {\mathbb {C} }\colon |z|\leq 1\}/(z\sim e^{2\pi i/3}z{\mbox{ whenever }}|z|=1)}$.
4. Find all the connected 2-sheeted and 3-sheeted covering spaces of the "figure eight space" ${\displaystyle S^{1}\vee S^{1}}$ (two circles joined at a point), up to isomorphism of covering spaces without base points.
5. Let ${\displaystyle a}$ and ${\displaystyle b}$ be the generators of ${\displaystyle \pi _{1}(S^{1}\vee S^{1})}$ corresponding to the two ${\displaystyle S^{1}}$ summands. Draw a picture of the covering space of ${\displaystyle S^{1}\vee S^{1}}$ corresponding to the normal subgroup generated by ${\displaystyle a^{2}}$, ${\displaystyle b^{2}}$, and ${\displaystyle (ab)^{4}}$, and prove that this covering space is indeed the correct one.

Due Date

This assignment is due in class on Thursday February 28, 2008.

Just for Fun

• What happens if in problem 1 we consider infinitely many covering spaces. That is, is the product of an infinite family of covering spaces a covering space?
• This raises another question. A "pathwise totally disconnected space" is a space in which every path is a constant path. How much of the theory of covering spaces can be generalized to "coverings" in which the fibers are pathwise totally disconnected, instead of discrete?