Math 401: Curves and Surfaces, Fall 2019
Prof. Jo Nelson
Email: jo [dot] nelson [at] rice [dot] eduLectures: MWF 2-2.50 pm HBH 423
Recitations: Tuesdays 2:30-3:30 HBH 40
Office Hours:
Prof Jo: M 3-4 pm and W 12-1pm in HBH 402
Leo: W 3-4pm and R 5:30-6:30pm in HBH 040
Syllabus
Piazza
Textbook
The official textbook for the course is:S. Montiel and A. Ros, Curves and Surfaces Second Edition, GSM, Vol. 69 (The first chapter is available for free)
An informal blog post explaining the Gauss-Bonnet Theorem, which will give you a flavor of what topics we will study rigorously in this course.
Teaching Assistant
The teaching assistant for this course is Leo DiGiosia. He will grade homework and half of the exams.Homework
Undergraduate students should expect to spend 6 hours a week on homework in this course. Homework will count for 30% of your final grade, and you must upload your homework to gradescope by 5pm on Wednesdays. Clearly print your first and last name on your assignment and indicate those students that you worked with. Late homework will not be accepted. Your lowest homework score will be dropped.Exams
There will be one pledged take home midterm, worth 30% of your course grade, which you should spend no more than 5-6 hours actively working on. It will be made available on Monday September 30 and due by 5pm on Monday October 7. You are not permitted to work with other students and you are not permitted to consult the internet beyond the course Piazza page. You are allowed to refer to the course textbook but no other books.The final exam will count for 40% of your course grade. It is in the nonstandard format of Choose your own Differential Adventure! It is due Monday December 16 at 5pm. Collaboration with classmates during the proposal stage is encouraged. You may use outside resources with my permission.
In the event of illness or family emergency I must be notified ideally at least 24 hours in advance and documentation from your magister must be provided to me in order to receive accommodations.
Help
If you find yourself confused, please seek help sooner rather than later. I will be available to answer questions during my office hours as will Leo. You should use Piazza to post questions about the course, including questions about topics covered in class or regarding the homework.In order to receive disability-related academic accommodations, students must first be registered with the Disability Resource Center (DRC). Students who may need accommodations in this course should give me a written letter from the DRC within the first two weeks. More information on the DRC registration process is available online at https://drc.rice.edu/. Registered students must present an accommodation letter to the professor before exams or other accommodations can be provided. Students who have, or think they may have, a disability are invited to contact DRC for a confidential discussion.
Outline
This course is about the geometry of curves and surfaces in three-dimensional space. We will also study the ``intrinsic" geometry of surfaces: that is, geometric notions which are described just in terms of the surface and not in terms of an embedding into higher dimensional euclidean space. A central theme of this course will be to study different kinds of curvature - defined locally on a curve (in chapter 1 of the book) or surface (in chapter 3) - and how curvature relates to global properties of the curve or surface (in chapters 4, 6, 7, and 9). One of the main results in this direction which we will prove near the end of the course is the Gauss-Bonnet theorem (chapter 8).We will follow the modern point of view on differential geometry by emphasizing global aspects of the subject whenever possible. In order to do this, we will introduce the concept of Lebesgue measure and Lebesgue integrals and revisit multivariable calculus from this perspective (chapter 5). Time does not permit us to rigorously develop all these foundations, which are treated in Math 425/515 (not a pre-requisite).
This course is intended to be a precursor to graduate courses in differential geometry and topology. Thus more emphasis is placed on self-learning and lemmas and theorems will not typically be worked out in detail in lectures. I will state key lemmas and theorems and summarize the main points. You should expect to spend 1-2 hours a week reading the textbook each week.
- Plane and space curves (chapter 1)
- Surfaces in Euclidean space (chapter 2)
- The second fundamental form (chapter 3)
- Separation and Orientability (chapter 4)
- Integration on surfaces (chapter 5)
- Global extrinsic geometry (chapter 6)
- Intrinsic geometry of surfaces (chapter 7)
- The Gauss-Bonnet Theorem(chapter 8)
- Global geometry of curves (chapter 9)
Schedule & Assignments
| Date | Material Covered | Homework (Wednesdays) |
| 8/26 | 1: Curves and arclength | |
| 8/28 | 1: Plane curves | |
| 8/30 | 1: Space curves | HW 1 LaTeX Due 9/4 |
| 9/2 | Labor Day | |
| 9/4 | 2: Surfaces and parametrizations | |
| 9/6 | 2: Change of parameters | HW 2 LaTeX Due 9/11 |
| 9/9 | 2: Differentiable functions and the tangent plane | |
| 9/11 | 2: Differentials Part I | |
| 9/13 | 2: Interlude on pringles and transversality | HW 3 LaTeX Due 9/18 |
| 9/16 | 3: Normal fields and orientation | |
| 9/18 | 3: Gauss map Short movie ``Outside In" |
|
| 9/20 | 3: Second fundamental form (last section covered on Midterm) | HW 4 LaTeX Due 9/25 |
| 9/23 | 3: Normal sections | |
| 9/25 | 3: Second fundamental form revisited | |
| 9/27 | 3: Continuity of Curvature | |
| 9/30 | 4: Separation MIDTERM HANDED OUT |
Midterm LaTeX Due 10/7 |
| 10/2 | 4: Jordan-Brouwer separation theorem | |
| 10/4 | 4: Tubular neighborhoods | 10/7 | MIDTERM DUE 5: Integrable functions and integration |
| 10/9 | 5: Change of variables and Fubini | HW 5 LaTeX Due 10/16 |
| 10/11 | 5: Area formula | |
| 10/14 | Fall Break | |
| 10/16 | 5: Divergence theorem and Brouwer fixed point theorem | HW 6 LaTeX Due 10/23 |
| 10/18 | 6: Reflections on eggs and tube eggs | |
| 10/21 | 6: Positively curved surfaces | |
| 10/23 | All the scattered things about parallel surfaces | HW 7 LaTeX Due 10/30 |
| 10/25 | 6: Minkowski formulas | |
| 10/28 | 6: The Alexandrov theorem | |
| 10/30 | Remarkable Pizza is seriously remarkable 7: Rigid motions and isometries |
HW 8 LaTeX Due 11/6 |
| 11/1 | 7: Gauss' Theorema Egregium Wikipedia animation |
|
| 11/4 | 7: Geodesics Informal blog post Gory details for a sphere |
|
| 11/6 | 7: Geodesics are trippy on an ellipsoid On a donut On a cone |
HW 9 LaTeX Due 11/13 |
| 11/8 | 7: Geodesics Maps with Least Distortion between surfaces |
11/11 | 7: The exponential map is the Azimuthal equidistant projection |
| 11/13 | 7: The exponential map | HW 10 LaTeX Due 11/25 |
| 11/15 | 8: Intro to Gauss-Bonnet and Euler Characteristic | |
| 11/18 | 8: Degree of maps between compact surfaces | 11/20 | 8: Homotopies and Brower's furry cat   |
Differential Adventure Proposal Due 12/2 |
| 11/22 | 8: Index of a critical point of a vector field | 11/25 | 8: Gauss-Bonnet Theorem |
| 11/27 | No Class | |
| 12/2 | 8: Gradient vector fields and GB upgrade | |
| 12/4 | Classification of Surfaces | |
| 12/6 | Manifolds and more | Completed Differential Adventure Write Up Due Monday 12/16 |