PROBLEM Here is a surprisingly intriguing challenge posed on Euclidea, a mobile app for Euclidean constructions: Construct a 60° angle through both a point $P$ and an external (infinite) line $\mathscr{l}$ using:
- Only three lines at most, OR
- Only four elementary Euclidean constructions at most.
HINTS FROM EUCLIDEA The problem is not solved until the line from $P$ to the appropriate point in $\mathscr{l}$ is fully constructed. Also, the variants can be solved by the following ordered sequences of moves:
- Variant 1: Circle, circle, perpendicular bisector.
- Variant 2: Circle, circle, circle, line.
DEFINITIONS Only unmarked straightedges and collapsing compasses may be used. The following table shows how moves are scored.
- Construct a point: 0 lines (L), 0 elementary Euclidean moves (E).
- Marking the intersection of two curves with a point: 0L, 0E.
- Construct a new line (segment): 1L, 1E.
- Construct an old line (segment): 1L, 1E.
- Construct a circle (non-collapsible compass): 1L, 1E.
- Construct the perpendicular bisector of a line segment: 1L, 3E.
- Construct a new line perpendicular to an old line: 1L, 3E.
- Construct an angle bisector: 1L, 4E.
RESEARCH Constructing a 60° angle involving only $\mathscr{l}$ is well-attested. Unfortunately, there are no questions on Mathematics Stackexchange about the $P$-constrained versions above. A Google search does not reveal anything promising.
BEST ATTEMPT YET The following figure accompanies the construction below, where the given and goal are shown as an inset:
- Construct $\bigcirc{A}$ centered on a point $A$ (in red) in $\mathscr{l}$ and with radius $AP$ [1L, 1E running total].
- Let $B$ be the rightmost point where $\bigcirc{A}$ $\cap$ $\mathscr{l}$ [1L, 1E running total].
- Construct $\bigcirc{B_{big}}$ centered on $B$ and with radius $AB$ [2L, 2E running total].
- Construct $\bigcirc{B_{small}}$ centered on $B$ and with radius $AP$ [3L, 3E running total].
- Let $C$ be the uppermost point where $\bigcirc{A}$ $\cap$ $\bigcirc{B_{big}}$ [3L, 3E running total].
- Construct $\bigcirc{C}$ centered on $C$ and with radius $AC$; $m\angle{ABC} = 60°$ [4L, 4E running total].
- Let $D$ be the leftmost point where $\bigcirc{C}$ $\cap$ $\bigcirc{B_{small}}$ [4L, 4E running total].
- Construct $\overline{DP}$ [5L, 5E running total].
- Let $E$ be the point where $\overline{DP}$ $\cap$ $\mathscr{l}$. $m\angle{PEB} = 60°$, which was what we wanted. [5L, 5E running total].