Proving that there are infinitely many points on the unit circle such that the distance between any two of them is a rational number.

Question

Having trouble solving this Math contest problem.

Prove that there are infinitely many points on the unit circle such that the distance between any two of them is a rational number.

It's obvious to see that there are infinitely many points on a unit circle such that the distance between two points on a unit circle is rational and it's also obvious that there are infinitely many rational distances between two points. But how in the world can you construct an infinite set of points such that the distance between any two points is rational?

Answer 1

If $z_1$, $z_2 \in \mathbb{C}$ then $|z_1^2 - z_2^2| = |z_1-z_2|\cdot |z_1 + z_2|$. If moreover $|z_1| = |z_2|$ then $|z_1^2 - z_2^2|$ equals twice the area of the rhombus on the vectors $z_1$, $z_2$.

So now consider a set of points $M = \{z_n \ | z_n \in \mathbb{Q}(i), |z_n| = 1\}$. The set $\{z_n^2 \ | \ z_n \in M \}$ will work ( can you see why ? $\ $ $\bf{A:}$ The area of the said rhombus is rational)

Note that $M = \{-1\} \cup \{ \frac{1-t^2}{1+t^2} + i \frac{2 t}{1+t^2} \ |\ t \in \mathbb{Q} \}$

$\bf{Added:}$ For reference purposes, the set is

$$N= \{P_t\colon =\left(\frac{1-6 t^2 + t^4}{(1+t^2)^2}, \frac{4t(1-t^2)}{(1+t^2)^2}\right) \ | \ t\in \mathbb{Q} \}\cup \{(1,0)\}$$

We calculate

$$d(P_s, P_t) = \frac{4 |(s-t)(1+s t)|}{(1+s^2)(1+t^2)}\\ d(P_t, (1,0) ) = \frac{4|t|}{1+t^2}$$

Answer 2

Points on the unit circle may be written parametrically as $(\cos2\theta,\sin2\theta)\,$ ($\theta\in \Bbb R$). The distance between two such points with parameters $\theta_i$ and $\theta_j$ is $$d_{ij}:=2|\sin(\theta_i-\theta_j)|=2|\sin\theta_i\cos\theta_j-\cos\theta_i\sin\theta_j|.$$ Now we can define $\theta_k$, for example, by $$\cos\theta_k= \frac{k^2-1}{k^2+1}\quad\text{and}\quad\sin\theta_k=\frac{2k}{k^2+1}\quad(k\in\Bbb N).$$ Then $d_{ij}$ is rational for all $i,j\in\Bbb N$.

(Remark: I don't know why @RobertIsrael deleted his (to me) perfectly good answer, which was essentially the same as mine. If he cares to reinstate his answer, then I will delete this one.)