AMATH 353
SLN 0000, TBA TBA, TBA
(Prerequisites: AMATH 351 or MATH 307)

Fourier Analysis and Partial Differential Equations


Instructor:

 Professor W. Criminale
Guggenheim 405A
tel: 543-9506
fax: 685-1440
lascala@amath.washington.edu
office hours: TBA

TA:

 Tom Darrow
Guggenheim 405D
tel: 685-0319
fax: 685-1440
tdarrow@amath.washington.edu
office hours: Tuesday 1:30-2:30
Thursday 1:30-2:30

Course Description

Foundations and definitions; Heat equation, wave equation, and Laplace's equation; Separation of variables technique for solutions; Initial-value, finite boundary-value problems; Fourier series in context of solving heat equation; Fourier sine and cosine series; Complete Fourier series. Fourier and Laplace transforms; Solving partial differential equations in semi-infinite and infinite domains; D'Alembert's solution for wave equation; method of characteristics for solving general first order partial differential equations.

Textbook

Farlow, S.J. Partial Differential Equations for Scientists and Engineers. John Wiley & Sons, 1982. Available at the University Bookstore.
Additional Notes: From time to time, additional notes and supplements will be put on course web or distributed in class.

Syllabus

(a) Introduction, bases
(b) Physical Origins of Partial Differential Equations
(c) Types of Partial Differential Equations
(d) Diffusion Examples; Solutions by Separation of Variables
(e) Fourier Series, Eigenfunction Expansions
(f) Wave Examples; Solutions by d'Alembert's Method
(g) Nonhomogeneous Partial Differential Equations
(h) Solutions of Laplace's Equation
(i) Utility of Fourier and Laplace Transforms
(j) First Order Partial Differential Equations; Method of Characteristics

Learning Objectives and Instructor Expectations

Although the subject matter of Partial Differential Equations can be made rather difficult, I will attempt to present the course material in as simple a manner as possible. More theoretical aspects, such as proofs, will not be given or required. Instead, applications and the physical bases will be emphasized.

I will let you know clearly what you need to learn and what can be omitted. Homework is used to reinforce class lectures and not as a way to introduce material that is not covered in class. Exams will emphasize basic techniques as applied to simple and fundamental problems. There will be no deliberately obscure questions in exams to test your mental dexterity.

Schedule and Homework

Follow links in the table below to obtain a copy of the homework in PostScript (.ps) or Adobe Acrobat (.pdf) format. You may also obtain here solutions to some of the homework and exam problems. An item shown below in plain text is not yet available. For additional information regarding viewing and printing the homework and solution sets, click here.

Homework and Quizzes Homework Due Date Homework Problem Sets Homework Solutions
First day of classes Monday, January 3
Homework#1 due Friday, January 14 Homework #1 (.ps, .pdf) HW #1 Solutions (.ps, .pdf)
Martin Luther King Day Monday, January 17 No class
Homework#2 due Friday, January 21 Homework #2 (.ps, .pdf) HW #2 Solutions (.ps, .pdf)
Homework#3 due Friday, January 28 Homework #3 (.ps, .pdf) HW #3 Solutions (.ps, .pdf)
Homework#4 due Friday, February 4 Homework #4 (.ps, .pdf) HW #4 Solutions (.ps, .pdf)
Quiz#1 Friday, February 11
Homework#5 due Friday, February 18 Homework #5 (.ps, .pdf) HW #5 Solutions (.ps, .pdf)
President's Day Monday, February 21 No class
Homework#6 due Friday, February 25 Homework #6 (.ps, .pdf) HW #6 Solutions ( .pdf)
Homework#7 due Friday, March 11
Note the change of date!		 Homework #7 (.ps, .pdf) HW #7 Solutions (.ps, .pdf)
Last day of classes Friday, March 11
Quiz #2 Monday, March 14 8:30-10:20 am

Grading

Your course grade will be based on a balance of (a) all homework assignments (1/2), and (b) two quiz scores at 1/4 each.
You may view your homework and exam grades on-line.

Tutorials

No on-line tutorials have been assigned for AMATH 353.

<lascala@amath.washington.edu> Sat Jan 15 15:58:00 2005