I'm doing a course in elementary euclidean geometry and I'm studying the properties of inscribed and circumscribed polygons and I've come to the following question:
For which $n$ there exist NON-regular* (1) equilateral circumscribed $n$-gons; (2) equiangular inscribed $n$-gons.
So far, not considering degenerated cases we have $n\ge 3$ and I've managed to excludes triangles and pentagons and find rhombi for (1) and rectangles for (2), however I'm not able to find a general procedure to follow.
I'm allowed to use every elementary geometrical fact (like symmetries, proportions, congruence and so on) and even a little of algebra and Cartesian geometry, however I'd prefer a coordinate-free solution.
EDIT: The definition of a regular polygon is a polygon both equilateral and equiangular, so a non-regular polygon is a polygon which is at least equilateral or equiangular and not both. A circumscribable/inscribable polygon is a polygon which can be circumscribed/inscribed by a circle.
It turns out that they exist if and only if $n$ is even.
Depending on your proof for the cases $n=3$ and $5$, you may have shown that the polygon must have alternating (every other) angles equal (in the equilateral case) or alternating sides (in the equiangular case) equal. If $n$ is odd, then you get every angle/side by starting with one and counting every other angle/side going around the circle, so this implies that the polygon is regular.
The converse is also true, and this gives you a construction for even $n$.
If you want to spoil the problem, take a look at this article.