Triangle Tiling: The case $3\alpha + 2\beta = \pi$
Abstract
An -tiling of triangle by triangle (the `tile') is a way of writing as a union of copies of overlapping only at their boundaries. Let the tile have angles , and sides . This paper takes up the case when . Then there are (as was already known) exactly five possible shapes of : either is isosceles with base angles , , or , or the angles of are , or the angles of are . In each of these cases, we have discovered, and here exhibit, a family of previously unknown tilings. These are tilings that, as far as we know, have never been seen before. We also discovered, in each of the cases, a Diophantine equation involving and the (necessarily rational) number that has solutions if there is a tiling using tile of some not similar to . By means of these Diophantine equations, some conclusions about the possible values of are drawn; in particular there are no tilings possible for values of of certain forms. We prove, for example, that there is no -tiling with prime when . These equations also imply that for each , there is a finite set of possibilities for the tile and the triangle . (Usually, but not always, there is just one possible tile.) These equations provide necessary, and in three of the five cases sufficient, conditions for the existence of -tilings.
Keywords
Cite
@article{arxiv.1206.2229,
title = {Triangle Tiling: The case $3\alpha + 2\beta = \pi$},
author = {Michael Beeson},
journal= {arXiv preprint arXiv:1206.2229},
year = {2019}
}
Comments
94 pages, 27 figures. This version adds the theorem that N cannot be prime for tilings of the form treated in the paper, and also corrects and improves some proofs; and improves one of the tiling-equation theorems to "necessary and sufficient" instead of just "necessary"