Principles of Nature: towards a new visual language
© 20032008 copyright Wayne Roberts. All rights reserved.
The Eutrigon Theorem  a new* twin to the theorem of PythagorasThis web page is reproduced from the author's book Principles of nature; towards a new visual language, WA Roberts P/L Canberra. 2003. [Used with permission of the author] Edited and reformatted for the web, including animated diagrams and additional commentary by the author. Introduction Scale structure theory has implications not only to the units and measurement of areas but also to triangle classification as we have seen. Particularly pertinent to the theorem presented here on this page is the implementation of the equitriangular unit of area (etu) as we defined earlier. We will also later use our new knowledge of the area of a eutrigon (in terms of these relative units of area, etu) in the algebraic interpretation of the geometric construction (figure ET2) below — a form of resonant scale structure (in the terminology of the new theory) — that visually proves the theorem. the Eutrigon Theorem—Geometric Form The area of any eutrigon (shaded in figure ET1) is equal to the sum of the areas of the equilateral triangles on its legs a and b, minus the area of the equilateral triangle on its hypotenuse, c.
Figure ET2 Detailing the proof (see figure ET3)
Now, some readers may not be satisfied that in the 'look & see' proof given above, that eutrigon Q may be any eutrigon . Before we prove this more rigorously let us imagine whether it is so. Imagine an animation of equilateraltriangle C rotating while maintaining its equilateral shape but varying in size such that its vertices 'slide along' the outer equilateral triangle it is touching...[I've provided such an animated version below and added some colour to jazz it up a bit! It autoloops a few times with a pause in between. If it has already been through its routine by the time you get to this part of the page, just click the 'refresh button' in your browser window, and it will start over.]
Figure ET4 For an elaboration of the proof that "Q" in Figure ET3 covers every possible eutrigon shape, see here.

