Given an ellipse, we want to draw a set of tangents to it, which are orthogonal to each other. We are looking for a synthetic way; not through algebra or trigonometry.
I know how to construct one tangent: Given any point $P$ on the ellipse, we connect it with the two foci, say $F_1$ and $F_2$ and then we bisect angle $F_1PF_2$. The bisector is the "normal". Then we draw an orthogonal line to the bisector, from point $P$f and this is our tangent.
I am trying to think of a way to construct another tangent, orthogonal to it. Clearly the normal of the second tangent will be orthogonal to the 1st normal. We are looking for the single point $Q$ (or maybe 2 points), for which, the 2nd normal will bisect angle $F_1QF_2$ but I can't think of any way to construct it.
Any ideas? Thank you!
There is a simple way to construct a second tangent, perpendicular to the first one you constructed at $P$. Let the normal at $P$ intersect again the ellipse at $N$ and let $M$ be the midpoint of $PN$. The line passing through $M$ and the center $O$ of the ellipse will then intersect the ellipse at two points $Q$ and $Q'$, with the property that the tangents at both points are parallel to $PN$, and hence perpendicular to the first tangent.
As I wrote in a comment, the intersections between the tangents at $Q$ and $Q'$ and the tangent at $P$ lie on the director circle of the ellipse.