This is the webpage for the course Geometry and Algorithms in Three-Dimensional Modeling, Spring 2016, Oklahoma State University.

Course Syllabus

Classes will take place on Tuesdays and Thursdays, 10:30 - 11:45am, in MSCS 514, and will consist of lectures on the mathematical underpinnings of 3D design software, and "workshop classes", spent learning the use of the software and working on projects. We will also use the 3D printing lab, MSCS 421. Students in the class will have 24 hour keycard access to the lab with their university ID card.

Lectures

We will cover a number of sections from the course text, Applied Geometry for Computer Graphics and CAD (Springer Undergraduate Mathematics Series) 2nd Edition, by Duncan Marsh. (The text is freely available in electronic form from library.okstate.edu.) We will quickly go through parts of chapters 1-3 (transformations, homogeneous coordinates), and mostly concentrate on chapters 6-9 (Bézier curves, B-splines and surfaces).

Homeworks

Homeworks will consist of standard problem sets to be handed in in class, or virtual 3D models to be handed in via D2L, or real-life 3D printed models to be handed in in class.

Tutorials

One cannot effectively learn how to use a piece of software by listening to lectures. Rather, one should use the software. The modelling homework sets and projects will give concrete goals to guide exploration of the software. Students will also follow tutorials.

Midterms

There will be two in-class midterms, to be held on Thursday 18th February and Thursday 31st March. There will be no final exam.

Projects

There will be three major projects due throughout the semester. The following schedule and topics are tentative.

Project 1: Goblet

Design and 3D print a goblet. This will likely be a surface of revolution (although if you wish you may depart from this). The goblet should hold precisely 100ml of water. The shape should be interesting in some way, either mathematically, culturally, and/or aesthetically. Along with the 3D print, students will complete a two page writeup on the mathematics and other relevant details of the design, and present their work to the class.

Project 2: Programming project

Produce a model (an artwork, an illustration, etc.) using some form of programming. Some possible ideas: Show a parametrised curve in space (a graph, the path of an object in motion etc.), show the graph of a function of two variables, make a tree-like fractal (or perhaps investigate L-systems), simulate a natural process (nautilus shell, pinecone etc.).

Project 3: Illustrate something mathematical

Produce a model illustrating a mathematical object, process, algorithm etc. The model may be drawn from your previous mathematics classes, or (even better) mathematics that is new to you. I can give you references to read. For example there are many ideas in symmetry or knot theory or other areas of mathematics that are accessible and would be good to illustrate with a 3D printed model.

The "make something cool" alternative

For any of the three graded projects, you can come to me before the initial "project proposal due" date, and suggest doing some entirely different project, drawn from your personal interests, other classes, or anything else you want to make. If the project has a suitable amount of mathematical content, then you may replace the graded project with your own.

Resources

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