EECS 225A Spring 2007

schedule resources

catalog description

 

225A.  Digital Signal Processing. (3)   Three hours of lecture per week. Prerequisites: 123 and 126 or solid background in stochastic processes. Advanced techniques in signal processing. Stochastic signal processing, parametric statistical signal models, and adaptive filtering. Application to spectral estimation, speech and audio coding, adaptive equalization, noise cancellation, echo cancellation, and linear prediction.

practical

 

Class: 258 Cory Hall, Wednesdays 12:30-2, Fridays 1-2:30

Instructor: Michael Gastpar

Office Hours: Mondays 11-12 and Wednesdays 2-3 in 265 Cory Hall.

announcements

textbook

 

Monson H. Hayes, Statistical Digital Signal Processing and Modeling, Wiley, 1996 (ISBN 0471594318) [homepage]

 

In addition, various resources (Web and handouts) will be used to supplement the text.

course topics

 

With signal processing becoming ubiquitous in today's computer literate world, a large number of application areas are growing in importance, both in industry and in the research community, such as seismic signal processing, speech data processing, medical image processing, radar signal processing, and sensor array processing. These problems have many different aspects, and a corresponding number of different solutions have been explored.

 

Signal Models (7 lectures)

 

Signal Representation and Approximation (8 lectures)

 

Signals, Systems, Noise (14 lectures)

  • Estimation Theory (Wiener, Kalman, Adaptive, Neural networks...)
  • Detection Theory (Neyman-Pearson, etc)
  • System Identification

 

student responsibilities

 

First and foremost, please read the announcements at the top of this page regularly.

Students are also reminded of the Departmental Policy on Academic Dishonesty and are also urged to also read and abide by the professional ethics represented in the IEEE Code of Ethics. Especially relevant in the latter are the two guidelines:

 

grades

 

The components of the course will be weighted as follows in the final grade. The final grades will be set by matching a curve to the final course averages.

 

Component

Weight

Comments

Homework

10%

Lecture Scribing
5%
Each student will do 2-3 lectures (Instructions)

In-class Midterm

15%

80 minute open-book exam

Takehome Midterm

20%

Project

5%(prop)

10%(review)

15%(pres)

20%(report)

In small groups (1-3 students), you will select a subarea of the class and explore the related literature. You will select around 5 papers and discuss and extend their contributions in a short report.

 

agenda

 

Exam

Date and Time

Location

Coverage

In-class Midterm

March 7 @ 12:30-2

TBD

TBD
Project Proposals
March 16 @ midnight
Via e-mail

Takehome Midterm

April 5 @ 12:30 - April 10 @ 11

TBD
Project Review Meetings
Week of April 16-20
265 Cory
Project Report Drafts
May 7 (Monday) @ midnight
Via e-mail
Project Presentations
May 14 (Monday), 3-6:30pm
299 Cory

Project Final Report

May 15 @ midnight

Via e-mail

acknowledgement

This web page is mostly drawn from the web page of Prof. D. G. Messerschmitt (Spring 2005).