Modular origami 30 units1/20/2024 ![]() Incidentally, if you want to make a Sonobe construction based on an elevation of a cube, it is possible. ![]() It’s the elevation of a single equilateral triangle, thought of as having a “front” and “back” face (or “obverse” and “reverse”, if you like) - in other words, a degenerate two-faced polyhedron, in which both faces share the same three edges and have collapsed onto one another. What about the three-unit construction? That would have to be the elevation of a two-faced structure - and it is. That principle is in fact the point of the last Math Monday’s installment, in which lopping four of the corners off of a cube of cheese resulted in a regular tetrahedron and four isosceles pyramids.īut we digress. What? That’s right, the elevation of a regular tetrahedron with isosceles-right-triangle pyramids is precisely a cube. What about the other two constructs? Well, the six-unit construction is an elevation of a regular tetrahedron. Each elevation has three times as many faces as the underlying polyhedron, but each Sonobe unit contributes two isosceles triangles, which explains why you need one and a half times as many Sonobe units as faces of the original polyhedron. Returning to the picture above, if you’re familiar with the regular octahedron and icosahedron, it’s not too hard to see that the 30-unit construction is an elevated icosahedron and the 12-unit construction is an elevated octahedron. In the case of Sonobe construction, that’s a pyramid just the right height to be made out of isosceles right triangles. In effect, it glues a pyramid onto each of the faces of the original polyhedron. What’s an elevation of a polyhedron? It’s what you get when you add a new vertex in the center of each face and lift each of these vertices up away from the center of the polyhedron, leaving them connected to the surrounding edges. And the best way to understand their shapes mathematically is to think of them as the elevations of various simpler shapes. In fact, all of the faces of all of the models here are those same isosceles right triangles. Despite any appearances to the contrary from the photo, this does not yield a tetrahedron, but rather a trigonal bipyramid with all isosceles right triangular faces, each one 1/16th the area of the original square you started with. The fewest Sonobe units you can get to close up into something (other than a flat packet) is three, shown at bottom left of the picture. Here’s a sort of visual primer of the first set of constructions (put together by Adam Sawicki) that you might encounter in this way. (Hint: Even if it may be origamically unorthodox, for rough exploratory constructions you can fold at least three stacked sheets of paper at a time through the main folds, just separating them for those last small triangle folds and the tuck to produce three finished units.) Once you have a supply of units, start tucking pointy corners into pockets, trying to be semi-systematic, and see what you come up with. Verrill) to produce a parallelogram with two pockets, just right for tucking in the pointy ends of other parallelograms, as illustrated here. ![]() ![]() To make Sonobe units, start with squares of any foldable material you like: office paper, construction paper, grocery bags, aluminum foil, or even (for a much floppier final result) gingham for that matter, and follow the simple instructions found here (provided by H. One of the simplest and most versatile of the modular units, there’s so much to say about Sonobe that today we’re going to start from the basics (parallelogram one?) and next time we’ll take it to places I hope you’ve never seen it go before. There have been numerous installments of Math Monday on origami or kirigami of one mathematical form or another, but today is the first time we’ve covered a classic workhorse from this genre: The Sonobe modular origami unit. ![]()
0 Comments
Leave a Reply.AuthorWrite something about yourself. No need to be fancy, just an overview. ArchivesCategories |