Math 615 —
Mathematical Methods for Physics
Fall 2002
Instructor:
Dan Barbasch
Time: MWF
12:20-1:10
Room:
Malott 206
Prerequisites:
- A knowledge of complex variable theory up to and including evaluation
of integrals using the residue theorem.
- Finite dimensional vector spaces up to and including diagonalization
of hermitian matrices.
- Fourier Series
- Separation of variables of partial differential equations.
Grading:
| Homework |
40%
|
| Midterm |
30%
|
| Final |
30%
|
| TOTAL |
100%
|
Exams: There will be a Midterm exam at the end of
October.
Homework: The homework is very important.
It defines what the material of the course is. There will be a homework
assignment for every week.
Final: The final covers all the material in the course
equally and is given during regular exam period.
Syllabus for 615
1. Hilbert Spaces
a. Definitions and Completeness
b. Bessel's inequality
c. Orthonormal bases
d. Parseval`s equality
2. Generalized Functions (following notes by R. Strichartz)
a. Basic properties and examples
b. Differentiation of generalized functions
c. Fourier transforms
d. Applications to PDE's
e. Green's functions
3. Ordinary Differential Equations
a. Green's functions for boundary value problems
b. Eigenfunction expansions
c. Completeness of eigenfunctions (continued in 616)
4. Asymptotic Expansions
a. Definition of order of growth and asymptotic expansions
b. Method of integration by parts
c. Laplace's method
d. Method of stationary phase
e. Method of steepest descent (following reference of Bender and Orszag)
4. Optional: If time permits we will cover some topics on Lie algebras
and quantum groups.
Last modified:
April 7, 2003
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