Difference between revisions of "Math 565: Differential Geometry"

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(New page: == Catalog Information == === Title === Differential Geometry === Credit Hours === 3 === Prerequisite === Math 316. === Description === This course is designed to provide students...)
 
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=== Description ===
 
=== Description ===
  
This course is designed to provide students with a rigorous treatment of the theory of differential equations.
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This course is designed to provide students with a rigorous treatment of the theory of differential geometry.
  
 
== Desired Learning Outcomes ==
 
== Desired Learning Outcomes ==

Revision as of 16:52, 20 August 2008

Catalog Information

Title

Differential Geometry

Credit Hours

3

Prerequisite

Math 316.

Description

This course is designed to provide students with a rigorous treatment of the theory of differential geometry.

Desired Learning Outcomes

This course is aimed at graduate students in Mathematics as well as graduate students in Physics and Engineering. This course contributes to all the expected learning outcomes of the Mathematics M.S. and Ph.D. The topics include the differential topology, Riemannian metrics, geodesics, curvature, and integration on manifolds.

Prerequisites

Students should have taken Math 316 prior to taking this course. Math 316 provides a rigorous background of analysis that is needed to understand many of the proofs in this course.

Minimal learning outcomes

Students should achieve mastery of the topics below. This means that they should know all relevant definitions, full statements of the major theorems, and examples of the various concepts. Further, students should be able to solve non-trivial problems related to these concepts, and prove theorems in analogy to proofs given by the instructor.

  1. Differential topology
    • Differentiable manifolds and smooth maps
    • Tangent space, tangent bundle, derivative of a smooth map
    • Immersions, submersions, and embeddings
    • Orientation
    • Vector fields, brackets
  2. Riemannian metrics
    • Definition of Riemannian metrics
    • Affine connections
    • Riemannian connections
  3. Geodesics
    • Definition of geodesics
    • Geodesic flow
    • Minimizing properties of geodesics
    • Exponential map
    • Convex neighborhoods
  4. Curvature
    • Definitions of curvature, curvature tensor
    • Second fundamental form
    • Sectional and Ricci curvature
    • Jacobi fields
  5. Integration on manifolds
    • Tensor and vector bundles
    • Exterior algebra
    • Differential forms and exterior derivative
    • Stokes Theorem


Additional topics

These are at the instructor's discretion as time allows examples are: Hopf-Rinow theorem, spaces of constant curvature, De Rham cohomology, fixed points and intersection numbers, and Morse theory.

Courses for which this course is prerequisite

None.