Mathematics 282: Elliptic Partial Differential Equations

Mathematics 282: Elliptic Partial Differential Equations (Spring 2002)

Instructor

Description

In this course we study concepts and tools which are used in much of rigorous mathematical analysis. The course centers around elliptic P.D.E.'s such as Laplace's or Poisson's equation, but much of what we study is used more generally.

We will begin with a systematic development of the Fourier transform, distributions or generalized functions, and their relationship. (E.g., the transform of a constant function is a delta function.) We review some properties of harmonic functions and study the representation of solutions of $\Delta$ u = f by singular integrals. We will see how boundary value problems for the Laplacian can be written in terms of singular integrals, and find the solution by solving integral equations on the boundary. We will learn about Sobolev spaces of functions having a certain number of derivatives in a weak sense in L². We will then study existence and regularity of elliptic boundary value problems in this L² point of view. Further topics may be chosen as time permits.

Prerequisites

The student should have taken a course like our PDE I (Math 232) and measure and integration (Math 241), or have equivalent background. Our other graduate PDE course, Math 281, is quite independent and is not required. Some acquaintance with functional analysis is helpful, especially compact operators, but is not essential. A student who is concerned about his/her background should speak to the instructor.

Text(s)

We will use the text by Folland, Introduction to Partial Differential Equations, second edition. For the L² theory of elliptic equations, we will use another reference, probably Evans' P.D.E., but only Folland's book is required.

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Last modified: 17 October 2001