Tag: geometry

Sonobe modules

Some of the Maths & Crafts students volunteered in February to help Trefor Bazett run an origami event as part of a day of math and engineering fun on campus (organized in partnership with Let’s Talk Science). Our event centred on Sonobe modules.

What is a Sonobe module? Many origami geometry models are modular, or based on units (see PHiZZ and Wireframe cube). The Sonobe module is a one-paper unit that is named for Mitsunobu Sonobe. It may have been created by Toshiba Takahama (they were coauthors and members of the same origami group), or it may have been invented by someone else and named for the first person to mention it in a publication (in 1968).
Image of a single Sonobe unit.
Sonobe unit.
Use: Three Sonobe modules lock together to form a tetrahedron corner (much like the PHiZZ module).
Three Sonobe units locked together.

One you have folded some Sonobe units, a good starting model is to assemble them into a cube:

Sonobe cube.

You can build other three-dimensional shapes with them too: a “triakis octahedron” or a “triakis icosahedron”. There are some examples of triakis octahedra in the Elliot building origami display, and there is an image of a triakis icosahedron at the end of this post.

The word “triakis” means that each face of the original shape has been replaced by a tetrahedron, which is the Platonic solid formed by four equilateral triangles. Because each face of an octahedron is an equilateral triangle, as is each face of an icosahedron, those shapes are suitable for the “triakis” treatment.

Questions to ponder (some hints below):

  1. How many Sonobe units do you need to build a cube?
  2. If you wanted to “properly colour” your cube, how many colours would you need?  Here we just mean that two papers of the same colour shouldn’t be attached to each other.
  3. Why is the cube special? The other models are “triakis” things; why isn’t the cube?
  4. How many pieces of paper would a triakis icosahedron need? 
  5. How many colours to properly colour the triakis octahedron? triakis icosahedron? (Three are certainly needed, because the units are assembled in trios.)

Resources from Maths Crafts New Zealand

Hints and answers to my questions:

  1. A cub needs six Sonobe modules. There are at least two ways to count it! First way: each Sonobe module is going to end up with its square inner bit being the face of a cube. How many faces has a cube got? Second way: each triple of Sonobe modules is going to form the corner of a cube; how many corners is each module involved in, and how many corners has a cube got?
  2. You’ll need at least three colours for any of these models, because Sonobe units lock together in trios. For the cube, three colours suffice.
  3. The “cube” is actually a “triakis tetrahedron”, so it’s not as special as it seems! This might take some drawing to work out; you might find it helpful to imagine what is left over if you slice each vertex off of a cube.
  4. An icosahedron has 20 faces, each of which is replaced by a trio of Sonobe units, and each unit participates in two faces, so you need 30 pieces of paper.
  5. For the triakis octahedron and the triakis icosahedron, three colours suffice (the triakis icosahedron pictured below is properly three-coloured). It is harder to properly three-colour the triakis icosahedron, though!
Sonobe triakis icosahedron.

PHiZZ Modules

Thomas Hull, in his book Project Origami, presents the PHiZZ Module (Pentagon Hexagon Zig Zag module). It is sometimes hard to see how these modules fit together, particularly if you are working from a static diagram. In this video, I start with a sort of stop-motion demonstration of how to fold the module itself, and then show you how to fit them together. Watch the whole thing for a time-lapse of me assembling a whole buckyball, with a brief cameo by my cat.

Click on the picture to watch the video.

Elliot Building Mathematical Origami display

Visit the classroom wing of the Elliot Building to see a display of mathematical origami starting in early December 2022. We hope our mathematical art brightens your December exam period!

Most of the models were constructed by members of the Association for Women in Mathematics student chapter at UVic and their friends. A few of the models you will see are listed below, and I will create some more detailed blog posts here for a few of them too, if you would like to learn more.

The Miura Map Fold

Koryo Miura, professor emeritus at the University of Tokyo, developed this fold in the 1970s, as a way of folding things like solar panel arrays so that they could be easily opened and closed for use in spacecraft. When used on somewhat rigid paper, the Miura Map Fold lets you unfold (and refold) your paper by just pulling (and pushing) on a pair of opposite corners.

For more details, visit https://en.wikipedia.org/wiki/Kōryō_Miura.

Self-similar Wave

From Thomas Hull’s book Project Origami, this is a self-similar origami model and can go on as long as your paper, and skill, permits.

Hyperbolic Paraboloid

Another model from Thomas Hull’s book Project Origami, this model might remind you of a surface from Multivariable Calculus. This model can also become as detailed as your skill allows.

Hexahedron

This model is due to Molly Kahn, and is an example of modular origami. The final shape is built from three identical units, which lock together.

Five Intersecting Tetrahedra

A tetrahedron is a platonic solid having four faces, each of which is an equilateral triangle. This model consists of five wireframe models of tetrahedra, interlaced together. Each tetrahedron has six edges, so it took one student 30 units (Francis Ow’s 60-degree unit) and about nine hours to build this model, following instructions from Thomas Hull’s book Project Origami.

Pentagon Hexagon Zig-Zag modules

This module is due to Thomas Hull, and is also called the PHiZZ module. It is useful for constructing wireframe models whose faces are pentagons or hexagons, because those result in sphere-like models. Graph theorists will recognize them as three-regular planar graphs, and many of our models are also properly three-edge-coloured because our graphs are Hamiltonian. The PHiZZ module can also be used to create a wireframe model of the torus, by including faces with more edges so as to introduce negative curvature. The models we built are listed below.

  • Dodecahedron: this is a platonic solid having 12 faces, each of which is a regular pentagon. It requires 30 PHiZZ modules.
  • Buckyball: familiar to both chemists and football fans, this wireframe model has 20 faces that are regular hexagons and 12 faces that are regular pentagons.  It requires 90 PHiZZ modules.
  • Torus: there are many models out there; we followed one due to the topologist dr. sarah-marie belcastro. It requires 84 PHiZZ modules.

Sonobe modules

Either due to Toshie Takahama or to Mitsunobu Sonobe, the Sonobe module  is great for building all sorts of models. The models we built are listed below, and we followed instructions for making the module from Maths Craft New Zealand.

  • Cube: this is a platonic solid having 6 faces, each of which is a square. It requires 6 Sonobe modules.
  • Triakis octahedron: this is related to a regular octahedron, but each face of the octahedron has a pyramid built over it. It requires 12 Sonobe modules.

More platonic solids

You will find a wireframe model of a cube (following instructions from Tomoko Fuse’s book The Complete Book of Origami Polyhedra), which required 12 units to build.

You might wonder what is inside that cube! It is an octahedron, yet another platonic solid, which has 8 faces that are each equilateral triangles. This model demonstrates that the octahedron is dual to the cube. You will also find some octahedra on their own, not inside a cube. These octahedra are built from “water bomb” modules, and although I don’t know who to credit for the original design you can find instructions here. Each one requires 6 units to construct.

Recommended resources

Tomato Fuse, The Complete Book of Origami Polyhedra.

Mark Bolitho, The Art And Craft of Geometric Origami.

Thomas Hull, Project Origami.