Description

This course is being completely revised this year.

This course provides a broad introduction to computer graphics and imaging. Topics: Input and output devices such as cameras and displays, graphics hardware and software, interactive techniques and the model-view-controller design pattern, typography and page layout, light and color representations, tone reproduction, image filtering, sampling, aliasing and antialiasing, compression, two- and three-dimensional geometry and transformations, modeling techniques including curves and surfaces, reflection models and illumination algorithms, and basic methods for animation.

Prerequisites

CS107, MATH 103.

Programming using C/C++ and OpenGL and use of common graphics tools such as drawing programs and image processing toolkits.

Masters students or students with a strong interest in continuing in graphics should take CS248.

Syllabus

Week

Dates

Tue

Thu

1

Jan 9, 11

Introduction

Drawing

2

Jan 16, 18

Geometry

Transforms

3

Jan 23, 25

Typography

Splines and Interpolation

4

Jan 30, Feb 1

Interaction

Model-View-Controller

5

Feb 6, 8

Light and Color

Digital Cameras

6

Feb 13, 15

Displays

Exposure and Tone Reproduction

7

Feb 20, 22

Mattes and Compositing

Filtering

8

Feb 27, Mar 1

Sampling: Aliasing and Antialiasing

Compression

9

Mar 6, 8

Digital Video and HDTV

Modeling

10

Mar 13, 15

Rendering

Animation

Information

Text and readings

There is one required text for the course.

In addition, one of the following books on OpenGL are recommended. The first one, the primer, is easy to read and gives a good overview of OpenGL. The second book, often called 'The Red Book" is more detailed and covers more advanced features. These books are recomended not required because most of this information can be found online. In particular, the 2nd Edition of the OpenGL Programming Guide is online.

Additional readings will be assigned from journals and conference proceedings, and excerpts from conference tutorials. Only papers NOT available online will be handed out in class. Readings for each lecture are available from the Lectures page.

Assignments and grading

The projects for this quarter involve enhancing a working ray tracer. We will use a a ray tracing system called pbrt. This system is a combined C++ codebase and textbook written in a literate programming language.

The first part of the course involves four assignments:

In the last part of the course you will enhance your system so that it is capable of reproducing an image of a real object, for example, a gemstone, a puff of smoke, a candle flame, etc. Check out the results produced by previous students.

Evaluation criteria: The first four structured programming assignments will each count as 10% of your grade, and the final programming project will count as 40%. The remaining 20% of your grade will be based on your comments on the lectures. There will be no exams.

Collaboration: For the first four programming projects, you may discuss the assignment with friends, but you are expected to implement your own solutions. On the last programming project, you are permitted (and encouraged) to form teams of two people and partition your planned extensions among the team members. Teams may discuss their project with other teams, but may not share code.

Late assignments: Since each assignment builds on the previous one, it is important that assignments be completed on time. To allow for unforeseeable circumstances, you will be allowed three weekdays of grace during the quarter. Beyond this, late assignments will be penalized by 10% per weekday that they are late. On the last programming project, neither the demo nor the writeup may be late. Incompletes in this course are given only in exceptional circumstances.

Hardware and software

You are welcome and encouraged to do class assignments on your own machines. Although PBRT builds successfully on most systems, the TAs will be able to provide support for compiling PBRT on Linux (on the public Stanford 'myth' machines, see below) and on Windows (via Visual Studio.net 2003). Check out the PBRTInfo page for information about working with the PBRT software.

If you do not wish to develop on a personal machine, you will have access to the 'myth' machines located on the second floor of Sweet Hall. These 3.2 Ghz DELL Dual-Xeon Linux boxes, named myth1 - myth29 are available for remote access. CS348b students are given non-exclusive priority access to these machines.

All students with leland accounts automatically have accounts on these machines. Home directories on these machines are shared with other Stanford Computing Clusters using AFS. If you do not have a leland account, consult this ITSS web page. Registered students will get an extra 200MB of disk quota for the quarter.

last edited 2007-01-25 19:38:34 by nit