AMATH 519
SLN 8390, WF 9:30-10:50, Mary Gates Hall 286

Introduction to Applied Stochastic Analysis

!!! Notice the Room Change !!!

Instructor:

Professor Hong Qian
Guggenheim 408K
tel: 543-2584
fax: 685-1440
qian@amath.washington.edu
office hours: TBA

Homework

Grades

Message Board

2000 Web Page

Course description

Textbook

Syllabus

Objectives

Schedule

Course Description

Introduction to the theory of probability and stochastic processes based on differential equations. Poison processes and Markov chains, Branching processes and renewal processes, continuous-time Markov processes and Brownian motions, introductory stochastic differential equations, stochastic fractals, large deviation principle and randomly perturbed dynamical systems.

Reference book

Grasman, J. and O.A. van Herwaarden Asymptotic Methods for Fokker-Planck Equation and the Exit Problem in Applications, Springer, 1999 Available at the University Bookstore.

Crispin W. Gardiner Handbook of Stochastic Methods: For Physics, Chemistry and the Natural Sciences, (Springer Series in Synergetics , Vol 13) Springer, 1996.

Emanuel Parzen Stochastic Processes, "Classics in Applied Mathematics", SIAM, 1999 Available at the University Bookstore.

Syllabus

1. Review on random variables, Markov chains and stationary processes
2. Radioactive decay and exponetial distribution
3. Poisson processes and Gamma distributions
4. Order statistics
5. Two-state chemical kinetics and continuous-time Markov chain (Q-processes)
6. Stationarity and correlation function
7. Reversibility and entropy production
8. Kolmogorov forward and backward equations
9. Branching processes
10. Renewal processes
11. Generating function and central limit theorem
12. random walk and birth-death processes
13. Brownian motion and diffusion
14. Brownian motion with a force field
15. Kramers' proble and transition-state theory
16. Brownian motion with boundary, first passage time problem
17. Brownian motion in 2-dimension, reversibility and circulation
18. Stochastic differential equations
19. Spectral analysis of Gaussian processes
20. Strongly correlated processes

Learning Objectives and Instructor Expectations

Stochastic analysis is a new way of reasoning which has wide application in all fields of science and engineering. Different from the traditional deterministic approach, stochastic analyses try to obtain useful information from seemingly random data, and stochastic models try to develop insights into the nature of randomness. The stochastic mathematics is particularly relevant to statistical physics, (just as calculus to mechanics and linear algebra to quantum mechanics), molecular biology, nanotechnology, signal processing and communications, and many branches of science and engineering, as well as economics and finance. The course will be taught from an application standpoint with examples from many different fields.

A minimal background in probability and familiarity with differential equations are required. Homeworks are used to reinforce class lectures. Exams will emphasize basic techniques as applied to basic problems.

Coutrse Notes

The course notes (.ps, .pdf) is still being developed. So only download the necessary portion.

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 Exams	Homework Due Date	Homework Problem Sets	Homework Solutions
First day of classes	Monday, March 26
Homework#1	due Wednesday, 4/11	Homework #1 (.ps, .pdf)
Homewor #2	due Wednesday, April 18	Homework #2 (.ps, .pdf)
Homework#3	due Wednesday, April 25	Homework #3 (.ps, .pdf)
Homework#4	due Wed, May 2	Homework #4 (.ps, .pdf)
Homework#5	due Wed, May 9	Homework #5 (.ps, .pdf)
Homework#6	due Wed, May 16	Homework #6 (.ps, .pdf)
Homework#7	due Wed, May 23	Homework #7 (.ps, .pdf)
Homework#8	due Wed, May 30	Homework #8 (.ps, .pdf)
Memorial Day	Monday, May 28	No class
Last day of classes	Friday, June 1
*Final Exam*	due 5PM Thursday, June 7	Final Exam (.ps, .pdf)

Grading

You may view your homework and exam grades on-line. Before doing so for the first time, you must request a password.

Tutorials

No on-line tutorials have been assigned for AMATH 519.

<qian@amath.washington.edu>

Fri Mar 16 11:14:24 PST 2001