CSC262 Computer Vision

Spring 2019

Synopsis: We explore some fundamentals of image processing and understanding, considering several image representations for extracting information and survey algorithms for solving a wide variety of problems, such as image de-noising, panorama creation, 3-D reconstruction, segmentation, and object recognition.

MWF

1:00-1:50 pm

Science 3819

Instructor: Jerod Weinman

Office: Noyce 3825

Phone: x9812

E-mail: [weinman]

Course web page: http://www.cs.grinnell.edu/~weinman/courses/CSC262/2019S

1 Accommodations
2 Overview
3 Texts
4 Class attendance
5 Schedule of topics
6 Activities
    6.1 Reading
    6.2 Participation
    6.3 Laboratory exercises and write-ups
    6.4 Exams
    6.5 Independent project
7 Grading
8 Academic honesty
9 Deadlines
10 Getting Help
    10.1 Discussion with Piazza
    10.2 Office Hours
    10.3 Email

1 Accommodations

If you have any disability that requires accommodations, please meet with me right away so that we can work together to find accommodations that meet your learning needs. You will also need to provide documentation of your disability to the Coordinator of Disability Services, Autumn Wilke, located on the 3rd floor of the Rosenfield Center (x3124).

Please also note that I require your accommodations. The synthetic fragrances found in deodorants, lotions, after shave, body sprays, laundry products, perfume, cologne, etc. make many people who suffer with asthma, allergies, environmental sensitivities, cancer, and migraines much sicker. I am sensitive to many such chemicals you may not even notice, so please try to avoid using such scented products before coming to class and especially if you visit my office.

2 Overview

How can we make computers understand images? What information is contained in an image and how can a meaningful representation be extracted? The problems of computer vision are two-fold. First, how can we take a two-dimensional image and reconstruct the three-dimensional world it came from? Second, how can we understand and recognize objects from those three-dimensional worlds?

Computer vision draws on a surprisingly large and diverse set of other fields, including psychology, neuroscience, mathematics, photogrammetry, optics, physics, signal processing, pattern recognition, artificial intelligence, and philosophy. We will try to find a way to glean what we need from each of these in a truly liberal (as in "liberal arts") fashion.

In this course, we will examine computational approaches to problems in low-level visual processing as well as some applications in higher-level vision.

Our major objectives for this course include:

Understanding the fundamental problems in computer vision
Learning both new and classical approaches to vision problems
Finding and appreciating limitations and caveats of models and algorithms

Why take it?

Computers can do many things much better than humans, but this area is one where humans still excel. If you are interested in an exciting interdisciplinary field with many open problems and practical applications, this course is for you.

What do I need to know?

This course assumes you have

experience with programming in both the functional and imperative paradigms.
fluency in some basic computational ideas like encapsulation and code re-use
mathematical maturity, especially familiarity with multivariate calculus and linear algebra.¹

3 Texts

Due to discrepancies between topics or details appropriate to an undergraduate course, we have no single, official textbook. Instead, we will use selected readings from a variety of texts, which will be available on the course web page, PioneerWeb, and E-Reserves:

David Forsyth and Jean Ponce, Computer Vision: A Modern Approach, Prentice Hall, 2003.
Richard Szeliski, Computer Vision: Algorithms and Applications, Springer, 2011.
Emanuele Trucco and Alessandro Verri, Introductory Techniques for 3-D Computer Vision, Prentice Hall, 2008.
Ian Goodfellow, Yoshua Bengio, and Aaron Courville, Deep Learning, MIT Press, 2016.

Our laboratory exercises will be done in MATLAB. This software is available on the MathLAN, but if you wish to have MATLAB on your own personal computer, a student version may be purchased from http://www.mathworks.com/store, http://www.journeyed.com, or http://www.academicsuperstore.com.

Two well-organized, regularly updated, additional resources on the web include a manually categorized research bibiliography and a compendium.

CVonline: The Evolving, Distributed, Non-Proprietary, On-Line Compendium of Computer Vision
Annotated Computer Vision Bibliography

4 Class attendance

Class meetings will involve a mix of discussions, collaborative activities, labs, and lectures. In short: You are expected to attend and actively participate in class. I am expected to make class worth attending.

Because is a collaborative, discussion-based course, your presence is integral to your learning. Thus, 1.5% will be deducted from your overall grade for each absence. I know that sometimes "things happen." Therefore, you will be granted one unexcused absence from class without penalty. However, this rebate is cancelled upon a second unexcused absence.

If you are absent, I would appreciate a written explanation (email is appropriate) to ease my concerns for your well-being. If you know in advance that you will be absent for any reason, please notify me in writing (again, email is fine) at least 7 days in advance to make arrangements for considering your absence excused.

Because I do not wish you to risk harm to yourself or others, I am likely to moderate penalties in case of illness.

Our discussions benefit from your contributions. However, if you do miss a class, you must first talk to a classmate about any material that you may have missed. After that, you may follow up with the instructor about any further questions or concerns.

5 Schedule of topics

The following is an approximate schedule of topics to be discussed during the course. See the web page schedule for daily details.

Week	Topic	Week	Topic
1	Matlab	8	Feature Matching
2	Image Formation	9	Stereo Geometry
3	Image Processing and Edge Detection	10	3-D Structure from Motion
4	Fourier Transforms	11	Color
5	Pyramids and Wavelets	12	Convolutional Networks
6	Feature Detection	13	Project Work and Reports
7	Feature Descriptors	14	Recent Research

6 Activities

Under a normal 16 credit load, I expect that you will spend 40 hours per week on your studies (class time, homework, and studying).² Thus, you should plan to spend a minimum of 10 hours/week on work for this course:

6.1 Reading

Our class meetings will be heavily discussion and lab-based, and this will require a significant amount of preparation on your part. You should check the class schedule for updates and read any material that has been assigned before coming to class. Reading texts entails the following:

Overview: You should quickly skim through the reading once to get an overview of the material to be covered, paying particular attention to subject headings and topic introductions. This first "reading" can (and should) be quick. (Expected time: 5 to 10 minutes.)
In-Depth: Next, read the material closely. Try to understand what individual steps of algorithms or mathematical equations are accomplishing. Not everything will make sense at this point, but hopefully many things will. (Expected time: 40 to 50 minutes.)
Final Notes: After carefully reading the material, mentally review and try making a few notes to yourself about what you think are the most important concepts being covered, as well as any . Bring your questions to class. I will ask for them. (Expected time: 5 to 10 minutes.)

Most readings for this class contain mathematics or algorithms that require a moderate amount of study. While I realize not everyone learns best by reading, you are asked to make your best effort and come to class with any questions you may have. Then we can proceed with discussion, examples, and exercises that enhance and clarify the material in class. Thus, you may consider answering the following questions to be part of your daily homework:

Identify the section or concept from today's reading that you find most confusing.
Briefly explain what you find confusing about it.

6.2 Participation

Because much of our work in this course involves collaboration and discussion, you will be evaluated on your participation.

Participating in class involves:

being present in class (physically and mentally)
coming to class on time
coming to class prepared
asking questions when appropriate
making positive contributions to class discussion by volunteering and when called upon
staying on task during collaborative exercises, and
working effectively with your group.

Students who regularly meet these criteria can expect to earn 3.75 (i.e., an A-) for their participation grade. I will reward students who regularly provide significant insights or guide discussion in productive ways with a higher participation score. Students who fail to participate regularly or who participate in counterproductive ways (e.g., by dominating the conversation or making inappropriate comments) can expect to earn a lower score.

6.3 Laboratory exercises and write-ups

Over the course of the term, nearly half of our class meetings will involve laboratory exercises. The "hands-on" labs will provide an instructor-assisted setting for you concretely engage in the material introduced in class and readings. Labs will be posted in advance of the date they are begun in class; because our in-class lab time is limited, it is very important for you to come prepared by reading the lab assignment beforehand, bringing any questions to resolve at the beginning of class. However, you should not work on the labs before class.

Contents

You will be expected to produce a formal write-up of your results, including images and figures as appropriate, a description of your method(s), and providing some conclusions. You will also submit your code. Please see the course web page (and individual labs) for further details on what you are expected to submit. Although we will begin the labs in class, you might not finish the technical material in class; it is unlikely you will finish the write-up.

Collaboration

You will typically complete these labs in pairs or groups, typically assigned on a rotating basis. Though you will start the lab as a group, I know it can be difficult to synchronize schedules on short time frames. Thus you may elect to complete your write-ups individually. In that case, you must clearly identify the contributions of your original partner(s) in the interest of academic honesty; to facilitate anonymous grading, simply cite which work was with your partner(s), but not their name(s). Conversely, everyone whose name appears on a submitted group lab report has the responsibility to ensure everyone fully understands the submission.

While you are welcome to discuss course concepts with others, solutions and any work you do and submit should be that of you and your group alone. (See Academic honesty, section 8 below.)

You are encouraged to use Piazza (see Section 10.1) for questions related to the course. If a post is related to an assignment, it must adhere to the standards of collaboration for that particular assignment.

Grading

Up to one third (33%) of the required labs may be graded on a completion basis only; such labs will weigh one-third of a fully assessed lab in the final grade calculation. You will not be told which labs are completion-graded because the instructor does not know in advance. Therefore, you should assume all labs will receive a full evaluation and produce a complete write-up for each. (Doing so will maximize your learning anyhow.)

6.4 Exams

As opportunities for you to demonstrate your image interpretation prowess and grasp of vision principles there will be two mid-semester exams, one before fall break and the other near the end of the semester. Although exam 2 is not intended to be cumulative, certain topics build on each other naturally and cannot be excluded.

Exam 1	Friday 1 March
Exam 2	Monday 6 May

6.5 Independent project

In the second half of the semester, you will propose and deploy an independent project that uses and builds on the principles we are learning in the class. You will have several weeks to work on the project and will be expected to conduct a small amount of mentored, but self-directed learning. Several example possibilities will be provided to get your imagination running. You will propose a project including a description of how a successful deployment will be produced, as well as milestones and benchmarks. You will share the results of your work in a final report and a presentation during finals week. Further details will be given near spring break.

7 Grading

My goal is for everyone taking this course to be able to demonstrate familiarity and fluency with the course concepts. I would be very happy if you all met the goals above and received "A"s. The following weighting will provide a basis for evaluation.

Laboratory Write-ups	55%
Participation	5%
Exams	20%
Project	20%

Grading will be based on the College's Grading System with the following brackets proposed:

Average at least	Receives	Grade Points	Definition
3.75	A	4.00	Excellent
3.50	A-	3.67	Excellent
3.16	B+	3.33	Good
2.83	B	3.00	Good
2.50	B-	2.67	Good
2.16	C+	2.33	Satisfactory
1.50	C	2.00	Satisfactory
0.50	D	1.00	Passing
0.00	F	0.00	Failing

To compensate for the unpredictability of learning exercises' outcomes, the bracket minimums (left column) may be adjusted downward (but not upward).

8 Academic honesty

As students, you are members of the academic community. Both the College and I expect the highest standards of academic honesty. (See the Grinnell College Student Handbook). Among other things, this means clearly distinguishing between work and ideas that are your own, and those that should be attributed to others. It is expected that the collaboration policies given in this syllabus and on particular assignments will be followed. In particular:

When you explicitly work as part of a group or team, you need not identify the work of each individual (unless I specify otherwise).
You may discuss (algorithms, ideas, approaches, etc.) described in the readings, during class, or explained in the lab assignments with anyone.
You may only discuss homework assignments (algorithms, solutions, write-ups, code, debugging, etc.) with your group members or the instructor.
All the work submitted (code, experimental data, write-ups, etc.) must be your own. Code or documentation provided by the instructor should be attributed, but no other code or written work (from any source) may be shared with others or copied for your own use.
All non-syntax consultations (including the textbook and language references) require formal citation within the related program or write-up.
Any conceptual contributions by others (not in your group) must be acknowledged and attributed in your report. That is you must give specific attribution for any assistance you receive. The suggested acknowledgment format is

"[Person X] helped me to do [thing Y] by [explaining Z]."
Any program results or output must be faithfully recorded, not forged. (A thoughtful explanation of unexpected behavior can often be a worthwhile submission and is much better than the alternative.)
You are responsible for safeguarding your work from being copied by others. This requires you to take reasonable precautions with hard copy printouts as well as file system permissions.

As an instructor, I will meet my obligation to bring any work suspected to be in violation of the College's Academic Honesty Policy to the attention of the Committee on Academic Standing, after which there is no recourse with me.

9 Deadlines

Assignments are due at the specified time and date. Assignments due on days for which you have a prior excused absence must still be submitted by the deadline.

A late penalty of one letter grade will be deducted in each subsequent twenty-four hour period after the deadline.

While the late penalty may seem extreme, here are two explanatory, if contradictory observations:

In the software production world, missing critical release deadlines can have significant consequences for individuals, teams, or even entire companies. Planning carefully with deadlines in mind is a good habit to develop. After all, in the academic world, missing assignment deadlines has consequences not only for your grade, but impacts your time available for other coursework and can negatively affect your overall, general wellness.
With each lab being worth a few percentage points of your grade, a one day late penalty amounts to less than 1% reduction in your overall grade. Using the grade brackets above, in most cases it would take nearly nine days of penalties on labs to lower your grade bracket. Hardly extreme.

Exception: Deadlines for MathLAN computer-based assignments will automatically be extended by at least one twenty-four hour period if MathLAN is down for an unscheduled period of three or more hours during the week preceding the assignment due date.

10 Getting Help

10.1 Discussion with Piazza

For class discussion, we will use Piazza, which is designed to get you help fast and efficiently from your classmates and myself. Rather than emailing questions, please to post your questions on Piazza, which is linked directly from the P-Web course or at https://piazza.com/grinnell/spring2019/csc262/home.

10.2 Office Hours

Please come by during my office hours to discuss the course content, get any extra assistance, or just talk about how the course is going. Note that if multiple students have similar questions or issues, we may work together as a group. If you cannot attend a scheduled office hour, you may also email me to schedule an appointment; please include 3-4 possible meeting times so that I can pick one that works for me.

I enjoy getting to know my students, but I prefer to reserve office hours for academic matters. If you would like to have a more informal conversation, I would be delighted to accept an invitation to eat lunch with you at the Marketplace.

10.3 Email

Email is also a reliable way to contact me, but please allow 24 hours for a response (except on weekends, when I do not regularly read email). You may also call me in my office (x9812) for more urgent matters (e.g., you will be missing a lab due to illness).

With thanks to Sam Rebelsky for the "Participation" section, and Janet Davis for the "Reading Suggestions" and other key policies.

Footnotes:

¹If linear algebra is a distant memory, I strongly urge you to study Eero Simoncelli's "A Geometric Review of Linear Algebra " http://www.cns.nyu.edu/~eero/NOTES/geomLinAlg.pdf.

²This is a minimum recommendation for achieving "satisfactory" (i.e., C-level) results. "Good" or "excellent" results may require a greater investment of time.