Math
544/545/546: Topology and Geometry of Manifolds
John
M. Lee
Autumn/Winter/Spring 2001-2002, MWF 1:30-2:20
Manifolds are arbitrary-dimensional generalizations of curves and
surfaces--spaces that locally look like Euclidean space but globally may not,
just as the sphere locally looks like the plane. They are the basic
subject matter of differential geometry, but also play a role in many other
branches of pure and applied mathematics. In the fall quarter we will
concentrate on the topology of manifolds, i.e., properties that are
invariant under continuous deformations. The main goals here are the
fundamental group, covering spaces, and the classification of compact
surfaces. The winter and spring quarters will be devoted to the study of smooth
manifolds, on which derivatives of functions and maps make sense.
Texts
- [Fall]
Introduction to Topological Manifolds, by J. M. Lee.
- [Winter/Spring]
Introduction to Smooth Manifolds, by J. M. Lee (to be published in
early 2002).
Prerequisites: In addition to the references below, much of the
prerequisite material is outlined in the appendices to the textbooks.
FOR FALL QUARTER:
- Set Theory:
Operations on sets, functions, equivalence and order relations, number
systems and cardinality, the axiom of choice. References: Principles of
Mathematical Analysis by Rudin, Chapter 1; Naive Set Theory by
Halmos.
- Analysis: Metric
spaces; convergence and continuity; open and closed sets; interior,
exterior, and boundary; compactness. Reference: Principles of
Mathematical Analysis by Rudin, Chapters 2,3,4.
- Algebra:
Elementary group theory, homomorphisms, isomorphisms, subgroups, normal
subgroups, permutation groups, cosets, quotient groups. Reference: Abstract
Algebra: An Introduction by Hungerford, Chapter 7.
FOR WINTER AND SPRING QUARTERS
- Linear algebra: Vector
spaces, subspaces, bases, dimension, matrices, determinants, change of
basis formulas, linear maps, kernel and image, inner products, orthonormal
bases, linear functionals, dual spaces. Reference: Linear Algebra
by Friedberg, Insel, and Spence.
- Multivariable calculus:
Partial derivatives; the total derivative as a linear map; Taylor's
formula in several variables; multiple integrals and the change of
variables formula; gradient, divergence, and curl; the theorems of Green,
Gauss, and Stokes; uniform convergence. References: Basic
Multivariable Calculus by Marsden, Tromba, and Weinstein; Principles
of Mathematical Analysis by Rudin, Chapters 5,6,7.
- Differential equations:
Basic facts about existence and uniqueness of solutions to ODEs;
elementary techniques for solving first-order equations and systems.
Reference: Ordinary Differential Equations by Birkhoff and Rota.
Homework and grading: There will be a homework assignment each week to
write up and hand in for a grade. Your grades will be based 2/3 on
homework and 1/3 on a take-home final exam.