CSE 6390D/PSYC 6225A 3.0(F) 2010 Computational Modeling of Visual Perception

Instructor Information: James H. Elder 0003G Computer Science and Engineering Building
tel: (416) 736-2100 ext. 66475 fax: (416) 736-5857
email: jelder@yorku.ca website: www.yorku.ca/jelder

General Description:

The goal of this course is to provide a framework and computational tools for modeling visual inference, motivated by interesting examples from the recent literature. Models may be realized as algorithms to solve computer vision problems, or may constitute theories of visual processing in biological systems. The foundation of the course is a treatment of visual processing as a problem of statistical estimation and inference, grounded in the ecological statistics of the visual world.

Syllabus

Lectures:

Assignments:

Assignment 1
- Instructions
- Dataset
- Code

Assignment 2
- Instructions
- Dataset
- Code

Guidelines for Application Paper Presentations:

For Everyone:

Everyone should read the paper prior to the presentation and be prepared to discuss it.

What is the objective?
What tools from the course are being used?
What did you not understand?

For the Presenter:

Your presentation should be around 10 minutes long – no more than 15! (About 10 slides)
What is the objective?
What tools from the course are being used and how?
What are the key ideas?
What are the unsolved problems?
Be prepared to answer questions from other students.

Approximate Schedule:

Week	Date	Topic	Required Readings	Additional Readings	Application Paper (Presenter)
1	M Sept 13 W Sept 15	Probability & Bayesian Inference Probability Distributions & Parametric Modeling	Bishop Ch 1.1-1.2.5 (29 pages) Bishop Ch 2.1-2.3 (skip 2.3.5) (43 pages)	Pearl Ch 1.4-1.6, 2 Howson & Urbach 1991 Prince Ch 1-4 Duda Ch 3.1-3.5
2	M Sept 20 W Sept 22	Probability Distributions & Parametric Modeling (cntd.) Non-Parametric Modeling	Bishop Ch 2.5 (7 pages)	Duda Ch 4.1-4.5	Comaniciu & Meer 2002 (Ron Tal)
3	M Sept 27 W Sept 29	Expectation Maximization	Prince Ch 5 (11 pages) Prince Ch 6.1-6.5, 6.8 (24 pages)	Bishop Ch 9	Stauffer & Grimson 1998 (Paria Mehrani) Weber & Perona 2000
4	M Oct 4 W Oct 6	Linear Subspace Models	Prince Ch 6.6-6.7, 6.9 (12 pages) Bishop Ch 12 (40 pages)	Duda Ch 10.13-10.14	Tenenbaum et al 2000 Roweis & Saul 2000 (Abdel-Hamid Ossama)
	M Oct 11 W Oct 13	Reading Week
5	M Oct 18 W Oct 20	Linear Regression	Bishop Ch 3 (36 pages)	Prince Ch 7.1-7.2	Moghaddam 2002 Cremers 2003 (Junjie Zhang)
6	M Oct 25 W Oct 27	Linear Classifiers	Bishop Ch 4.1-4.3 (34 pages)	Duda 5.1-5.8	Belhumeur et al 1997 (Brian Kim) Martin et al 2004 (Tareq Mohammad Adnan) - moved to Nov 1
7	M Nov 1 W Nov 3	Non-Linear Regression & Classification	Bishop Ch 6 (29 pages)	Prince Ch 7.3-7.4	Toyama & Blake 2001 Grochow et al 2004 (Anna Topol)
8	M Nov 8 W Nov 10	Sparse Kernel Machines	Bishop 7.1 (20 pages)		Agarwal & Triggs 2006 (Eduardo Corral Soto) Zhang et al 2007
9	M Nov 15 W Nov 17	Graphical Models: Introduction	Bishop Ch 8.1-8.3 (34 pages)		Freeman et al 2000 (Ravi Persad) Shi & Malik 2000 (Xiwen Chen)
10	M Nov 22 W Nov 24	Graphical Models: Inference	Bishop Ch 8.4 (25 pages)		Boykov & Funka-Lea 2006 (Chao Luo) He et al 2004 (Anthony Calce)
11	M Nov 29 W Dec 1	Graphical Models: Applications	Prince Ch 10-11 (56 pages)		Frey & Jojic 2005 Szeliski et al 2008 Friedman et al 2004 (Wendy Ashlock)
12	M Dec 6 W Dec 8	Sampling Methods	Bishop Ch 11 (32 pages)		Zhu 1999 Yuille & Kersten 2006 (Calden Wloka)

Main Texts:

C.M. Bishop Pattern Recognition and Machine Learning. New York: Springer, 2006. PRML Website
S.J.D. Prince Computer Vision Models. Available in draft form at http://computervisionmodels.blogspot.com/

Additional Readings:

Howson C. & Urbach P. (1991) Bayesian reasoning in science. Nature 350, 371-374.